diff --git a/EXAMPLE_MOD/BUNDLE/Coax_Gnd_EField.bundle b/EXAMPLE_MOD/BUNDLE/Coax_Gnd_EField.bundle deleted file mode 100644 index b4fa1ce..0000000 --- a/EXAMPLE_MOD/BUNDLE/Coax_Gnd_EField.bundle +++ /dev/null @@ -1,168 +0,0 @@ -v2.3.1 -Coax_Gnd_EField - 1 ! number of cables not including ground plane - 2 ! number of cables, cable name and x y coordinates follow... -coaxial_cable_02 - 0.0000000000000000 2.0000000000000000E-002 0.0000000000000000 x y coordinates and angle of cable -ground_plane - 0.0000000000000000 0.0000000000000000 90.000000000000000 x y coordinates and angle of ground plane - 6.1230317691118863E-017 1.0000000000000000 ground plane normal direction - 1 orientation of cables wrt ground plane - 3 # total number of conductors - 2 # total number of external conductors - 2 # dimension of the matrix system characterising the MTL propagation - 2 # number of domains - Domain number 1 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 1 - 2 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 2.50552594E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 1.06578826E-10 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.5055259369907356E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 10000000.000000000 # w normalisation constant - 2 # a order, a coefficients follow below: - 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - Domain number 2 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 2 - 3 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 6.60723411E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 1.68398764E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 6.6072341066465837E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.6839876385366454E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Global current domain transformation matrix, [MI] - 2 Dimension of [MI] - 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 - # Global voltage domain transformation matrix, [MV] - 2 Dimension of [MV] - 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 1.00000000E+00 - # Global domain based inductance matrix, [L] - 2 Dimension of [L] - 2.50552594E-07 0.00000000E+00 - 0.00000000E+00 6.60723411E-07 - # Global domain based capacitance matrix, [C] - 2 Dimension of [C] - 1.06578826E-10 0.00000000E+00 - 0.00000000E+00 1.68398764E-11 - Global domain based Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.5055259369907356E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 6.6072341066465837E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Global domain based Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 10000000.000000000 # w normalisation constant - 2 # a order, a coefficients follow below: - 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.6839876385366454E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor impedance models - 1 # Conductor impedance model type - 4.2000000000000002E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 1.4700000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 7.2179112513331222E-006 # shield thickness - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.29999999999999999 1.0000000000000000E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - 0 # Conductor impedance model type - # conductor x y positions - 0.0000000000000000 2.0000000000000000E-002 - 0.0000000000000000 2.0000000000000000E-002 - 0.0000000000000000 0.0000000000000000 -is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc - F 0 1 1 1 2 - T 1 2 2 1 3 - F 0 2 3 2 3 diff --git a/EXAMPLE_MOD/BUNDLE/Coax_Gnd_EField.bundle_spec b/EXAMPLE_MOD/BUNDLE/Coax_Gnd_EField.bundle_spec deleted file mode 100644 index a51c33e..0000000 --- a/EXAMPLE_MOD/BUNDLE/Coax_Gnd_EField.bundle_spec +++ /dev/null @@ -1,9 +0,0 @@ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -1 #Number of cables in bundle, cable list follows -coaxial_cable_02 -0.0 0.02 0 -ground_plane -no_laplace diff --git a/EXAMPLE_MOD/BUNDLE/FD_2_Wire.bundle b/EXAMPLE_MOD/BUNDLE/FD_2_Wire.bundle deleted file mode 100644 index 401a83b..0000000 --- a/EXAMPLE_MOD/BUNDLE/FD_2_Wire.bundle +++ /dev/null @@ -1,88 +0,0 @@ -v2.3.1 -FD_2_Wire - 2 ! number of cables not including ground plane - 2 ! number of cables, cable name and x y coordinates follow... -single_wire - 3.0000000000000001E-003 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable -single_wire - 0.0000000000000000 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable -no_ground_plane - 2 # total number of conductors - 2 # total number of external conductors - 1 # dimension of the matrix system characterising the MTL propagation - 1 # number of domains - Domain number 1 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 1 - 2 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 1.10268615E-06 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 1.00903603E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.1026861492333964E-006 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.0090360315349812E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Global current domain transformation matrix, [MI] - 1 Dimension of [MI] - 1.00000000E+00 - # Global voltage domain transformation matrix, [MV] - 1 Dimension of [MV] - 1.00000000E+00 - # Global domain based inductance matrix, [L] - 1 Dimension of [L] - 1.10268615E-06 - # Global domain based capacitance matrix, [C] - 1 Dimension of [C] - 1.00903603E-11 - Global domain based Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.1026861492333964E-006 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Global domain based Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.0090360315349812E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor impedance models - 1 # Conductor impedance model type - 1.9050000000000000E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 1.9050000000000000E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - # conductor x y positions - 3.0000000000000001E-003 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 -is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc - F 0 1 1 1 2 - F 0 1 2 2 2 diff --git a/EXAMPLE_MOD/BUNDLE/FD_2_Wire.bundle_spec b/EXAMPLE_MOD/BUNDLE/FD_2_Wire.bundle_spec deleted file mode 100644 index 35159c8..0000000 --- a/EXAMPLE_MOD/BUNDLE/FD_2_Wire.bundle_spec +++ /dev/null @@ -1,11 +0,0 @@ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -2 #Number of cables in bundle, cable list follows -single_wire -3.0e-3 0.0 0.0 -single_wire -0.0 0.0 0.0 -no_ground_plane -no_laplace diff --git a/EXAMPLE_MOD/BUNDLE/FD_ZT_Spacewire.bundle b/EXAMPLE_MOD/BUNDLE/FD_ZT_Spacewire.bundle deleted file mode 100644 index f39ba87..0000000 --- a/EXAMPLE_MOD/BUNDLE/FD_ZT_Spacewire.bundle +++ /dev/null @@ -1,2371 +0,0 @@ -v2.3.1 -FD_ZT_Spacewire - 1 ! number of cables not including ground plane - 1 ! number of cables, cable name and x y coordinates follow... -spacewire - 0.0000000000000000 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable -no_ground_plane - 13 # total number of conductors - 1 # total number of external conductors - 12 # dimension of the matrix system characterising the MTL propagation - 9 # number of domains - Domain number 1 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 1 - 2 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 4.82554527E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 2 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 2 - 9 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 2.68677221E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 3 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 3 - 3 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 4.82554527E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 4 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 4 - 10 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 2.68677221E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 5 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 5 - 4 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 4.82554527E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 6 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 6 - 11 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 2.68677221E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 7 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 7 - 5 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 4.82554527E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 8 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 8 - 12 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 2.68677221E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 9 - 5 number of conductors in this domain - terminal_conductor_list - 5 ! number of elements - 9 - 10 - 11 - 12 - 13 - Per-Unit-length Inductance Matrix, [L] - 4 Dimension of [L] - 1.84316340E-07 5.39918049E-08 3.13072143E-08 5.39881438E-08 - 5.39918049E-08 1.84319509E-07 5.39831349E-08 3.13087805E-08 - 3.13072143E-08 5.39831349E-08 1.84332861E-07 5.39800105E-08 - 5.39881438E-08 3.13087805E-08 5.39800105E-08 1.84326252E-07 - Per-Unit-length Capacitance Matrix, [C] - 4 Dimension of [C] - 8.10461294E-11 -2.09376538E-11 -1.93945500E-12 -2.09339121E-11 - -2.09376538E-11 8.10428561E-11 -2.09295921E-11 -1.94046442E-12 - -1.93945500E-12 -2.09295921E-11 8.10305676E-11 -2.09263826E-11 - -2.09339121E-11 -1.94046442E-12 -2.09263826E-11 8.10359177E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 4 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8431633950127683E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3991804942125864E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1307214294412399E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3988143811142728E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3991804942125864E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8431950926864742E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3983134865942790E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1308780454336153E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1307214294412399E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3983134865942790E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8433286095430486E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3980010475558027E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3988143811142728E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1308780454336153E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3980010475558027E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8432625193110273E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 4 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1046129434811950E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0937653783663186E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9394550041482759E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0933912129944583E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0937653783663186E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1042856062401645E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0929592068643844E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9404644230052484E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9394550041482759E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0929592068643844E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1030567551953145E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0926382619037599E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0933912129944583E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9404644230052484E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0926382619037599E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1035917699675297E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Global current domain transformation matrix, [MI] - 12 Dimension of [MI] - 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 - # Global voltage domain transformation matrix, [MV] - 12 Dimension of [MV] - 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 - # Global domain based inductance matrix, [L] - 12 Dimension of [L] - 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.84316340E-07 5.39918049E-08 3.13072143E-08 5.39881438E-08 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.39918049E-08 1.84319509E-07 5.39831349E-08 3.13087805E-08 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 3.13072143E-08 5.39831349E-08 1.84332861E-07 5.39800105E-08 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.39881438E-08 3.13087805E-08 5.39800105E-08 1.84326252E-07 - # Global domain based capacitance matrix, [C] - 12 Dimension of [C] - 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 8.10461294E-11 -2.09376538E-11 -1.93945500E-12 -2.09339121E-11 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -2.09376538E-11 8.10428561E-11 -2.09295921E-11 -1.94046442E-12 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.93945500E-12 -2.09295921E-11 8.10305676E-11 -2.09263826E-11 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -2.09339121E-11 -1.94046442E-12 -2.09263826E-11 8.10359177E-11 - Global domain based Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 12 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 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0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 6 6 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 6 7 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 6 8 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 6 9 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 6 10 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 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2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 8.0000000000000002E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 5.8594000000000002E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 6.7910018908980910E-003 6.3516651586671768 131.85223712596317 714.73088207712362 1550.1604988129416 1509.1499548754166 617.70419490065785 - 5 # b order, b coefficients follow below: - 1.0000000000000000 20.715352684308218 112.30217945904732 243.56691527043952 237.12345747204483 97.056063856769896 - # conductor x y positions - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 -is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc - F 0 1 1 1 2 - F 0 2 2 1 9 - F 0 3 3 1 3 - F 0 4 4 1 10 - F 0 5 5 1 4 - F 0 6 6 1 11 - F 0 7 7 1 5 - F 0 8 8 1 12 - T 2 9 9 1 13 - T 4 9 10 2 13 - T 6 9 11 3 13 - T 8 9 12 4 13 - F 0 10 13 1 13 diff --git a/EXAMPLE_MOD/BUNDLE/FD_ZT_Spacewire.bundle_spec b/EXAMPLE_MOD/BUNDLE/FD_ZT_Spacewire.bundle_spec deleted file mode 100644 index 19bf715..0000000 --- a/EXAMPLE_MOD/BUNDLE/FD_ZT_Spacewire.bundle_spec +++ /dev/null @@ -1,9 +0,0 @@ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -1 #Number of cables in bundle, cable list follows -spacewire -0.0 0.0 0 -no_ground_plane -no_laplace diff --git a/EXAMPLE_MOD/BUNDLE/Twisted_Pair_Over_Ground.bundle b/EXAMPLE_MOD/BUNDLE/Twisted_Pair_Over_Ground.bundle deleted file mode 100644 index 527349e..0000000 --- a/EXAMPLE_MOD/BUNDLE/Twisted_Pair_Over_Ground.bundle +++ /dev/null @@ -1,162 +0,0 @@ -v2.3.1 -Twisted_Pair_Over_Ground - 1 ! number of cables not including ground plane - 2 ! number of cables, cable name and x y coordinates follow... -twisted_pair - 0.0000000000000000 4.0000000000000001E-003 0.0000000000000000 x y coordinates and angle of cable -ground_plane - 0.0000000000000000 0.0000000000000000 90.000000000000000 x y coordinates and angle of ground plane - 6.1230317691118863E-017 1.0000000000000000 ground plane normal direction - 1 orientation of cables wrt ground plane - 3 # total number of conductors - 2 # total number of external conductors - 2 # dimension of the matrix system characterising the MTL propagation - 2 # number of domains - Domain number 1 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 1 - 2 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 5.17395547E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 2.15048247E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.1739554748668476E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.1504824721741357E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 2 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 2 - 3 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 6.38980930E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 1.74128836E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 6.3898092952216130E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.7412883618969838E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Global current domain transformation matrix, [MI] - 2 Dimension of [MI] - 5.00000000E-01 -5.00000000E-01 - 1.00000000E+00 1.00000000E+00 - # Global voltage domain transformation matrix, [MV] - 2 Dimension of [MV] - 1.00000000E+00 -1.00000000E+00 - 5.00000000E-01 5.00000000E-01 - # Global domain based inductance matrix, [L] - 2 Dimension of [L] - 5.17395547E-07 0.00000000E+00 - 0.00000000E+00 6.38980930E-07 - # Global domain based capacitance matrix, [C] - 2 Dimension of [C] - 2.15048247E-11 0.00000000E+00 - 0.00000000E+00 1.74128836E-11 - Global domain based Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.1739554748668476E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 6.3898092952216130E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Global domain based Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.1504824721741357E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.7412883618969838E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor impedance models - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 0.0000000000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 0.0000000000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 0 # Conductor impedance model type - # conductor x y positions - 0.0000000000000000 4.0000000000000001E-003 - 0.0000000000000000 4.0000000000000001E-003 - 0.0000000000000000 0.0000000000000000 -is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc - F 0 1 1 1 2 - F 0 2 2 1 3 - F 0 2 3 2 3 diff --git a/EXAMPLE_MOD/BUNDLE/Twisted_Pair_Over_Ground.bundle_spec b/EXAMPLE_MOD/BUNDLE/Twisted_Pair_Over_Ground.bundle_spec deleted file mode 100644 index c7b0fbf..0000000 --- a/EXAMPLE_MOD/BUNDLE/Twisted_Pair_Over_Ground.bundle_spec +++ /dev/null @@ -1,9 +0,0 @@ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -1 #Number of cables in bundle, cable list follows -twisted_pair -0.0 4.0e-3 0 -ground_plane -use_laplace diff --git a/EXAMPLE_MOD/BUNDLE/ZT_FD_Coax.bundle b/EXAMPLE_MOD/BUNDLE/ZT_FD_Coax.bundle deleted file mode 100644 index 3c5f92e..0000000 --- a/EXAMPLE_MOD/BUNDLE/ZT_FD_Coax.bundle +++ /dev/null @@ -1,170 +0,0 @@ -v2.3.1 -ZT_FD_Coax - 2 ! number of cables not including ground plane - 2 ! number of cables, cable name and x y coordinates follow... -bare_wire - 5.0000000000000001E-003 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable -coaxial_cable_01 - -5.0000000000000001E-003 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable -no_ground_plane - 3 # total number of conductors - 2 # total number of external conductors - 2 # dimension of the matrix system characterising the MTL propagation - 2 # number of domains - Domain number 1 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 2 - 3 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 2.50552594E-07 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 1.06578826E-10 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.5055259369907356E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 10000000.000000000 # w normalisation constant - 2 # a order, a coefficients follow below: - 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - Domain number 2 - 2 number of conductors in this domain - terminal_conductor_list - 2 ! number of elements - 1 - 3 - Per-Unit-length Inductance Matrix, [L] - 1 Dimension of [L] - 1.30449858E-06 - Per-Unit-length Capacitance Matrix, [C] - 1 Dimension of [C] - 8.52933132E-12 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.3044985756382986E-006 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.5293313218577504E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Global current domain transformation matrix, [MI] - 2 Dimension of [MI] - 0.00000000E+00 1.00000000E+00 - 1.00000000E+00 0.00000000E+00 - # Global voltage domain transformation matrix, [MV] - 2 Dimension of [MV] - 0.00000000E+00 1.00000000E+00 - 1.00000000E+00 0.00000000E+00 - # Global domain based inductance matrix, [L] - 2 Dimension of [L] - 2.50552594E-07 0.00000000E+00 - 0.00000000E+00 1.30449858E-06 - # Global domain based capacitance matrix, [C] - 2 Dimension of [C] - 1.06578826E-10 0.00000000E+00 - 0.00000000E+00 8.52933132E-12 - Global domain based Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.5055259369907356E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.3044985756382986E-006 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Global domain based Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 10000000.000000000 # w normalisation constant - 2 # a order, a coefficients follow below: - 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 0.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.5293313218577504E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor impedance models - 1 # Conductor impedance model type - 1.0000000000000000E-004 # conductor radius - 0.0000000000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 4.2000000000000002E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 1.4700000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 2.1653733753999367E-005 # shield thickness - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.10000000000000001 1.0000000000000001E-009 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor x y positions - 5.0000000000000001E-003 0.0000000000000000 - -5.0000000000000001E-003 0.0000000000000000 - -5.0000000000000001E-003 0.0000000000000000 -is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc - F 0 2 2 1 3 - F 0 1 1 1 3 - T 1 2 3 2 3 diff --git a/EXAMPLE_MOD/BUNDLE/ZT_FD_Coax.bundle_spec b/EXAMPLE_MOD/BUNDLE/ZT_FD_Coax.bundle_spec deleted file mode 100644 index 39c4169..0000000 --- a/EXAMPLE_MOD/BUNDLE/ZT_FD_Coax.bundle_spec +++ /dev/null @@ -1,11 +0,0 @@ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -2 #Number of cables in bundle, cable list follows -bare_wire -0.005 0.0 0 -coaxial_cable_01 --0.005 0.0 0 -no_ground_plane -no_laplace diff --git a/EXAMPLE_MOD/BUNDLE/ZT_FD_twinax.bundle b/EXAMPLE_MOD/BUNDLE/ZT_FD_twinax.bundle deleted file mode 100644 index 8a0a08f..0000000 --- a/EXAMPLE_MOD/BUNDLE/ZT_FD_twinax.bundle +++ /dev/null @@ -1,177 +0,0 @@ -v2.3.1 -ZT_FD_twinax - 1 ! number of cables not including ground plane - 1 ! number of cables, cable name and x y coordinates follow... -twinax_cable - 0.0000000000000000 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable -no_ground_plane - 3 # total number of conductors - 1 # total number of external conductors - 2 # dimension of the matrix system characterising the MTL propagation - 1 # number of domains - Domain number 1 - 3 number of conductors in this domain - terminal_conductor_list - 3 ! number of elements - 1 - 2 - 3 - Per-Unit-length Inductance Matrix, [L] - 2 Dimension of [L] - 4.02980604E-07 1.50754360E-07 - 1.50754360E-07 4.02980604E-07 - Per-Unit-length Capacitance Matrix, [C] - 2 Dimension of [C] - 7.22325649E-11 -2.70220800E-11 - -2.70220800E-11 7.22325649E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.0298060410845298E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.5075436047527605E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.5075436047527605E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.0298060410845298E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 7.2232564935120289E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.7022080023862092E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.7022080023862092E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 7.2232564935120276E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Global current domain transformation matrix, [MI] - 2 Dimension of [MI] - 1.00000000E+00 0.00000000E+00 - 0.00000000E+00 1.00000000E+00 - # Global voltage domain transformation matrix, [MV] - 2 Dimension of [MV] - 1.00000000E+00 0.00000000E+00 - 0.00000000E+00 1.00000000E+00 - # Global domain based inductance matrix, [L] - 2 Dimension of [L] - 4.02980604E-07 1.50754360E-07 - 1.50754360E-07 4.02980604E-07 - # Global domain based capacitance matrix, [C] - 2 Dimension of [C] - 7.22325649E-11 -2.70220800E-11 - -2.70220800E-11 7.22325649E-11 - Global domain based Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.0298060410845298E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.5075436047527605E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.5075436047527605E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.0298060410845298E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Global domain based Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 7.2232564935120289E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.7022080023862092E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.7022080023862092E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 7.2232564935120276E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor impedance models - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 1.5915494309189534E-005 # shield thickness - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.10000000000000001 1.0000000000000001E-009 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # conductor x y positions - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 - 0.0000000000000000 0.0000000000000000 -is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc - F 0 1 1 1 3 - F 0 1 2 2 3 - F 0 2 3 1 3 diff --git a/EXAMPLE_MOD/BUNDLE/ZT_FD_twinax.bundle_spec b/EXAMPLE_MOD/BUNDLE/ZT_FD_twinax.bundle_spec deleted file mode 100644 index 5e0fdcd..0000000 --- a/EXAMPLE_MOD/BUNDLE/ZT_FD_twinax.bundle_spec +++ /dev/null @@ -1,9 +0,0 @@ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -#MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -1 #Number of cables in bundle, cable list follows -twinax_cable -0.0 0.0 0 -no_ground_plane -no_laplace diff --git a/EXAMPLE_MOD/CABLE/bare_wire.cable b/EXAMPLE_MOD/CABLE/bare_wire.cable deleted file mode 100644 index d9b420a..0000000 --- a/EXAMPLE_MOD/CABLE/bare_wire.cable +++ /dev/null @@ -1,52 +0,0 @@ -v2.3.1 -cylindrical - 1 # cable type number - 1 # Total Number of conductors - 1 # Number of external conductors - 1 # Total number of domains (including external domain) - 0 # Number of internal conductors - 0 # Number of internal domains - 3 # Number of cable parameters - 1.0000000000000000E-004 - 1.0000000000000000E-004 - 0.0000000000000000 - 1 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 1.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 1.0000000000000000E-004 # conductor radius - 0.0000000000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - External to domain conductor current transformation matrix, MI - 2 Dimension of MI - 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 2 Dimension of MV - 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 1.00000000E+00 - # Local reference conductor for internal domains - 0 - # number of conductors in each domain - 2 - # External conductor information and dielectric model - 1 conductor type - 1.0000000000000000E-004 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 1.0000000000000000E-004 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 1.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/bare_wire.cable_spec b/EXAMPLE_MOD/CABLE/bare_wire.cable_spec deleted file mode 100644 index 7e608ef..0000000 --- a/EXAMPLE_MOD/CABLE/bare_wire.cable_spec +++ /dev/null @@ -1,15 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Cylindrical -1 #number of conductors -3 #number of parameters -0.1e-3 # parameter 1: conductor radius -0.1e-3 # parameter 2: dielectric radius -0.0 # parameter 3: conductivity -1 # number of frequency dependent parameters -# Dielectric relative permittivity model follows -1.0 # w normalisation constant -0 # a order, a coefficients follow below -1.00 -0 # b order, b coefficients follow below -1.0 diff --git a/EXAMPLE_MOD/CABLE/coaxial_cable_01.cable b/EXAMPLE_MOD/CABLE/coaxial_cable_01.cable deleted file mode 100644 index fcd3079..0000000 --- a/EXAMPLE_MOD/CABLE/coaxial_cable_01.cable +++ /dev/null @@ -1,101 +0,0 @@ -v2.3.1 -coax - 4 # cable type number - 2 # Total Number of conductors - 1 # Number of external conductors - 2 # Total number of domains (including external domain) - 1 # Number of internal conductors - 1 # Number of internal domains - 6 # Number of cable parameters - 4.2000000000000002E-004 - 1.4700000000000000E-003 - 2.5000000000000001E-003 - 50000000.000000000 - 0.0000000000000000 - 50000000.000000000 - 2 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 10000000.000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.6000000000000001 2.3999999999999999 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Dielectric filter number 2 - 10000000.000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.3999999999999999 2.2000000000000002 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 4.2000000000000002E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 1.4700000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 2.1653733753999367E-005 # shield thickness - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.10000000000000001 1.0000000000000001E-009 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - External to domain conductor current transformation matrix, MI - 3 Dimension of MI - 1.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 3 Dimension of MV - 1.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 - Domain number 1 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 2.50552594E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 1.06578826E-10 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.5055259369907356E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 10000000.000000000 # w normalisation constant - 2 # a order, a coefficients follow below: - 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Local reference conductor for internal domains - 2 - 0 - # number of conductors in each domain - 2 - 2 - # External conductor information and dielectric model - 1 conductor type - 1.4700000000000000E-003 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 2.5000000000000001E-003 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 10000000.000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.3999999999999999 2.2000000000000002 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/coaxial_cable_01.cable_spec b/EXAMPLE_MOD/CABLE/coaxial_cable_01.cable_spec deleted file mode 100644 index dbbaa5c..0000000 --- a/EXAMPLE_MOD/CABLE/coaxial_cable_01.cable_spec +++ /dev/null @@ -1,31 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Coax -2 #number of conductors -6 #number of parameters -4.2e-4 # parameter 1: inner conductor radius (m) -1.47e-3 # parameter 2: shield radius -2.5e-3 # parameter 3: outer insulation radius (m) -5.0e7 # parameter 4: inner conductor electric conductivity -0.0 # parameter 5: shield conductor thickness -5.0e7 # parameter 6: shield electric conductivity -2 # number of frequency dependent parameters -# Inner dielectric relative permittivity -1e7 # w normalisation constant -1 # a order, a coefficients follow below -2.6 2.4 -1 # b order, b coefficients follow below -1.0 1.0 -# Outer dielectric relative permittivity -1e7 # w normalisation constant -1 # a order, a coefficients follow below -2.4 2.2 -1 # b order, b coefficients follow below -1.0 1.0 -1 # number of frequency dependent transfer impedance models -# Transfer impedance model -1 # angular frequency normalisation -1 # order of numerator model -0.1 1e-9 # list of numerator coefficients a0 a1 a2... -0 # order of denominator model -1 # list of denominator coefficients b0 b1 b2... diff --git a/EXAMPLE_MOD/CABLE/coaxial_cable_02.cable b/EXAMPLE_MOD/CABLE/coaxial_cable_02.cable deleted file mode 100644 index 655ad0f..0000000 --- a/EXAMPLE_MOD/CABLE/coaxial_cable_02.cable +++ /dev/null @@ -1,101 +0,0 @@ -v2.3.1 -coax - 4 # cable type number - 2 # Total Number of conductors - 1 # Number of external conductors - 2 # Total number of domains (including external domain) - 1 # Number of internal conductors - 1 # Number of internal domains - 6 # Number of cable parameters - 4.2000000000000002E-004 - 1.4700000000000000E-003 - 2.5000000000000001E-003 - 50000000.000000000 - 0.0000000000000000 - 50000000.000000000 - 2 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 10000000.000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.6000000000000001 2.3999999999999999 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Dielectric filter number 2 - 10000000.000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.3999999999999999 2.2000000000000002 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 4.2000000000000002E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 1.4700000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 7.2179112513331222E-006 # shield thickness - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.29999999999999999 1.0000000000000000E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - External to domain conductor current transformation matrix, MI - 3 Dimension of MI - 1.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 3 Dimension of MV - 1.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 - Domain number 1 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 2.50552594E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 1.06578826E-10 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.5055259369907356E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 10000000.000000000 # w normalisation constant - 2 # a order, a coefficients follow below: - 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Local reference conductor for internal domains - 2 - 0 - # number of conductors in each domain - 2 - 2 - # External conductor information and dielectric model - 1 conductor type - 1.4700000000000000E-003 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 2.5000000000000001E-003 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 10000000.000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.3999999999999999 2.2000000000000002 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/coaxial_cable_02.cable_spec b/EXAMPLE_MOD/CABLE/coaxial_cable_02.cable_spec deleted file mode 100644 index a1c468b..0000000 --- a/EXAMPLE_MOD/CABLE/coaxial_cable_02.cable_spec +++ /dev/null @@ -1,31 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Coax -2 #number of conductors -6 #number of parameters -4.2e-4 # parameter 1: inner conductor radius (m) -1.47e-3 # parameter 2: shield radius -2.5e-3 # parameter 3: outer insulation radius (m) -5e7 # parameter 4: inner conductor electric conductivity -0.0 # parameter 5: shield conductor thickness -5e7 # parameter 6: shield electric conductivity -2 # number of frequency dependent parameters -# Inner dielectric relative permittivity -1e7 # w normalisation constant -1 # a order, a coefficients follow below -2.6 2.4 -1 # b order, b coefficients follow below -1.0 1.0 -# Outer dielectric relative permittivity -1e7 # w normalisation constant -1 # a order, a coefficients follow below -2.4 2.2 -1 # b order, b coefficients follow below -1.0 1.0 -1 # number of frequency dependent transfer impedance models -# Transfer impedance model -1 # angular frequency normalisation -1 # order of numerator model -0.3 1e-8 # list of numerator coefficients a0 a1 a2... -0 # order of denominator model -1 # list of denominator coefficients b0 b1 b2... diff --git a/EXAMPLE_MOD/CABLE/single_wire.cable b/EXAMPLE_MOD/CABLE/single_wire.cable deleted file mode 100644 index 74505d8..0000000 --- a/EXAMPLE_MOD/CABLE/single_wire.cable +++ /dev/null @@ -1,52 +0,0 @@ -v2.3.1 -cylindrical - 1 # cable type number - 1 # Total Number of conductors - 1 # Number of external conductors - 1 # Total number of domains (including external domain) - 0 # Number of internal conductors - 0 # Number of internal domains - 3 # Number of cable parameters - 1.9050000000000000E-004 - 5.0000000000000001E-004 - 50000000.000000000 - 1 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 100000000.00000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.6000000000000001 2.2500000000000000 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 1.9050000000000000E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - External to domain conductor current transformation matrix, MI - 2 Dimension of MI - 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 2 Dimension of MV - 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 1.00000000E+00 - # Local reference conductor for internal domains - 0 - # number of conductors in each domain - 2 - # External conductor information and dielectric model - 1 conductor type - 1.9050000000000000E-004 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 5.0000000000000001E-004 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 100000000.00000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 2.6000000000000001 2.2500000000000000 - 1 # b order, b coefficients follow below: - 1.0000000000000000 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/single_wire.cable_spec b/EXAMPLE_MOD/CABLE/single_wire.cable_spec deleted file mode 100644 index 48d509f..0000000 --- a/EXAMPLE_MOD/CABLE/single_wire.cable_spec +++ /dev/null @@ -1,15 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Cylindrical -1 #number of conductors -3 #number of parameters -1.905e-4 # parameter 1: conductor radius -0.5e-3 # parameter 2: dielectric radius -5e7 # parameter 3: conductivity -1 # number of frequency dependent parameters -# Dielectric relative permittivity model follows -1e8 # w normalisation constant -1 # a order, a coefficients follow below -2.60 2.25 -1 # b order, b coefficients follow below -1.0 1.0 diff --git a/EXAMPLE_MOD/CABLE/spacewire.cable b/EXAMPLE_MOD/CABLE/spacewire.cable deleted file mode 100644 index dfe475e..0000000 --- a/EXAMPLE_MOD/CABLE/spacewire.cable +++ /dev/null @@ -1,617 +0,0 @@ -v2.3.1 -spacewire - 6 # cable type number - 13 # Total Number of conductors - 1 # Number of external conductors - 10 # Total number of domains (including external domain) - 12 # Number of internal conductors - 9 # Number of internal domains - 13 # Number of cable parameters - 2.5000000000000001E-004 - 4.4999999999999999E-004 - 1.0000000000000000E-003 - 2.0000000000000000E-003 - 6.2500000000000001E-005 - 2.2000000000000001E-003 - 4.0000000000000001E-003 - 8.0000000000000002E-003 - 5.8594000000000002E-005 - 8.9999999999999993E-003 - 50000000.000000000 - 50000000.000000000 - 50000000.000000000 - 3 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 2.2500000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Dielectric filter number 2 - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 4.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Dielectric filter number 3 - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 2.2500000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 0.50000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 6.2500000000000001E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 - 5 # b order, b coefficients follow below: - 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 - 4 # Conductor impedance model type - 8.0000000000000002E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 5.8594000000000002E-005 # shield thickness - 628318530.71795857 # w normalisation constant - 6 # a order, a coefficients follow below: - 6.7910018908980910E-003 6.3516651586671768 131.85223712596317 714.73088207712362 1550.1604988129416 1509.1499548754166 617.70419490065785 - 5 # b order, b coefficients follow below: - 1.0000000000000000 20.715352684308218 112.30217945904732 243.56691527043952 237.12345747204483 97.056063856769896 - External to domain conductor current transformation matrix, MI - 14 Dimension of MI - 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 14 Dimension of MV - 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 - Domain number 1 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 4.82554527E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 2 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 2.68677221E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 3 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 4.82554527E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 4 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 2.68677221E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 5 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 4.82554527E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 6 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 2.68677221E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 7 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 4.82554527E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 3.38180465E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8255452695104504E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.3818046452081930E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 8 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 2.68677221E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 4.82242002E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.6867722148577511E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.8224200154968492E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Domain number 9 - 5 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 4 Dimension of L - 1.84316340E-07 5.39918049E-08 3.13072143E-08 5.39881438E-08 - 5.39918049E-08 1.84319509E-07 5.39831349E-08 3.13087805E-08 - 3.13072143E-08 5.39831349E-08 1.84332861E-07 5.39800105E-08 - 5.39881438E-08 3.13087805E-08 5.39800105E-08 1.84326252E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 4 Dimension of C - 8.10461294E-11 -2.09376538E-11 -1.93945500E-12 -2.09339121E-11 - -2.09376538E-11 8.10428561E-11 -2.09295921E-11 -1.94046442E-12 - -1.93945500E-12 -2.09295921E-11 8.10305676E-11 -2.09263826E-11 - -2.09339121E-11 -1.94046442E-12 -2.09263826E-11 8.10359177E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 4 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8431633950127683E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3991804942125864E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1307214294412399E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3988143811142728E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3991804942125864E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8431950926864742E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3983134865942790E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1308780454336153E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1307214294412399E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3983134865942790E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8433286095430486E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3980010475558027E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3988143811142728E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 3.1308780454336153E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.3980010475558027E-008 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.8432625193110273E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 4 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1046129434811950E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0937653783663186E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9394550041482759E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0933912129944583E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0937653783663186E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1042856062401645E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0929592068643844E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9404644230052484E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9394550041482759E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0929592068643844E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1030567551953145E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 3 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0926382619037599E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0933912129944583E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -1.9404644230052484E-012 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 3 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.0926382619037599E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 4 4 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 8.1035917699675297E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Local reference conductor for internal domains - 2 - 9 - 3 - 10 - 4 - 11 - 5 - 12 - 13 - 13 - 13 - 13 - 0 - # number of conductors in each domain - 2 - 2 - 2 - 2 - 2 - 2 - 2 - 2 - 5 - 2 - # External conductor information and dielectric model - 1 conductor type - 8.0000000000000002E-003 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 8.9999999999999993E-003 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 2.2500000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/spacewire.cable_spec b/EXAMPLE_MOD/CABLE/spacewire.cable_spec deleted file mode 100644 index 12a42ce..0000000 --- a/EXAMPLE_MOD/CABLE/spacewire.cable_spec +++ /dev/null @@ -1,51 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Spacewire -13 #number of conductors -13 #number of parameters -2.5e-4 # parameter 1: inner conductor radius (m) -4.5e-4 # parameter 2: inner dielectric radius (m) -1.0e-3 # parameter 3: inner conductor separation (m) -2.0e-3 # parameter 4: inner shield radius (m) -6.25e-5 # parameter 5: inner shield thickness (m) -2.2e-3 # parameter 6: inner shield jacket radius (m) -4.0e-3 # parameter 7: shielded twisted pair radius (m) -8.0e-3 # parameter 8: outer shield radius (m) -5.8594e-5 # parameter 9: outer shield thickness (m) -9.0e-3 # parameter 10: outer dielectric radius (m) -5e7 # parameter 11: inner conductor electric conductivity (m) -5e7 # parameter 12: inner shield electric conductivity (m) -5e7 # parameter 13: inner shield electric conductivity (m) -3 # number of frequency dependent parameters -# Inner dielectric relative permittivity -1e7 # w normalisation constant -0 # a order, a coefficients follow below -2.25 -0 # b order, b coefficients follow below -1.0 -# Inner shield dielectric relative permittivity -1e7 # w normalisation constant -0 # a order, a coefficients follow below -4.0 -0 # b order, b coefficients follow below -1.0 -# Outer dielectric relative permittivity -1e7 # w normalisation constant -0 # a order, a coefficients follow below -2.25 -0 # b order, b coefficients follow below -1.0 -2 # number of frequency dependent transfer impedance models -# Inner shield Transfer impedance mode -628318530.71795857 # angular frequency normalisation -6 # order of numerator model -2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 # list of numerator coefficients a0 a1 a2... -5 # order of denominator model -1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 # list of denominator coefficients b0 b1 b2... -# Outer shield Transfer impedance mode -628318530.71795857 # angular frequency normalisation -6 # order of numerator model -6.7910018908980910E-003 6.3516651586671768 131.85223712596317 714.73088207712362 1550.1604988129416 1509.1499548754166 617.70419490065785 # list of numerator coefficients a0 a1 a2... -5 # order of denominator model -1.0000000000000000 20.715352684308218 112.30217945904732 243.56691527043952 237.12345747204483 97.056063856769896 # list of denominator coefficients b0 b1 b2... -use_laplace diff --git a/EXAMPLE_MOD/CABLE/twinax_cable.cable b/EXAMPLE_MOD/CABLE/twinax_cable.cable deleted file mode 100644 index 67b724e..0000000 --- a/EXAMPLE_MOD/CABLE/twinax_cable.cable +++ /dev/null @@ -1,148 +0,0 @@ -v2.3.1 -twinax - 7 # cable type number - 3 # Total Number of conductors - 1 # Number of external conductors - 2 # Total number of domains (including external domain) - 2 # Number of internal conductors - 1 # Number of internal domains - 8 # Number of cable parameters - 2.5000000000000001E-004 - 4.4999999999999999E-004 - 1.0000000000000000E-003 - 2.0000000000000000E-003 - 0.0000000000000000 - 3.0000000000000001E-003 - 50000000.000000000 - 50000000.000000000 - 2 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 2.2500000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Dielectric filter number 2 - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 2.2500000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 4 # Conductor impedance model type - 2.0000000000000000E-003 # conductor radius - 50000000.000000000 # conductivity - 1.0000000000000000 # Resistance_multiplication_factor - 1.5915494309189534E-005 # shield thickness - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.10000000000000001 1.0000000000000001E-009 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - External to domain conductor current transformation matrix, MI - 4 Dimension of MI - 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 - 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 4 Dimension of MV - 1.00000000E+00 0.00000000E+00 -1.00000000E+00 -0.00000000E+00 - 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 - 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 - Domain number 1 - 3 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 2 Dimension of L - 4.02980604E-07 1.50754360E-07 - 1.50754360E-07 4.02980604E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 2 Dimension of C - 7.22325649E-11 -2.70220800E-11 - -2.70220800E-11 7.22325649E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.0298060410845298E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.5075436047527605E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 1.5075436047527605E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 4.0298060410845298E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 2 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 7.2232564935120289E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 1 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.7022080023862092E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - -0.0000000000000000 -2.7022080023862092E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 -Element: 2 2 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 7.2232564935120276E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Local reference conductor for internal domains - 3 - 3 - 0 - # number of conductors in each domain - 3 - 2 - # External conductor information and dielectric model - 1 conductor type - 2.0000000000000000E-003 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 3.0000000000000001E-003 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 10000000.000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 2.2500000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/twinax_cable.cable_spec b/EXAMPLE_MOD/CABLE/twinax_cable.cable_spec deleted file mode 100644 index 04d4711..0000000 --- a/EXAMPLE_MOD/CABLE/twinax_cable.cable_spec +++ /dev/null @@ -1,34 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Twinax -3 #number of conductors -8 #number of parameters -0.25e-3 # parameter 1: inner conductor radius (m) -0.45e-3 # parameter 2: inner dielectric radius (m) -1.0e-3 # parameter 3: inner conductor separation (m) -2.0e-3 # parameter 4: shield radius (m) -0.0 # parameter 5: shield thickness (m) -3.0e-3 # parameter 6: outer dielectric radius (m) -5e7 # parameter 7: inner conductor electric conductivity (m) -5e7 # parameter 8: shield electric conductivity (m) -2 #number of frequency dependent parameters -# Inner dielectric relative permittivity -1e7 # w normalisation constant -0 # a order, a coefficents follow below -2.25 -0 # b order, b coefficents follow below -1.0 -# Outer dielectric relative permittivity -1e7 # w normalisation constant -0 # a order, a coefficents follow below -2.25 -0 # b order, b coefficents follow below -1.0 -1 # number of frequency dependent transfer impedance models -# Transfer impedance model -1 # angular frequency normalisation -1 # order of numerator model -0.1 1e-9 # list of numerator coefficients a0 a1 a2... -0 # order of denominator model -1 # list of denominator coefficients b0 b1 b2... -no_laplace diff --git a/EXAMPLE_MOD/CABLE/twisted_pair.cable b/EXAMPLE_MOD/CABLE/twisted_pair.cable deleted file mode 100644 index 63deda7..0000000 --- a/EXAMPLE_MOD/CABLE/twisted_pair.cable +++ /dev/null @@ -1,87 +0,0 @@ -v2.3.1 -twisted_pair - 2 # cable type number - 2 # Total Number of conductors - 1 # Number of external conductors - 2 # Total number of domains (including external domain) - 1 # Number of internal conductors - 1 # Number of internal domains - 4 # Number of cable parameters - 2.5000000000000001E-004 - 1.0000000000000000E-003 - 4.4999999999999999E-004 - 0.0000000000000000 - 1 # number of frequency dependent dielectric models - # Dielectric filter number 1 - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 1.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Conductor impedance models - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 0.0000000000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - 1 # Conductor impedance model type - 2.5000000000000001E-004 # conductor radius - 0.0000000000000000 # conductivity - 1.5000000000000000 # Resistance_multiplication_factor - External to domain conductor current transformation matrix, MI - 3 Dimension of MI - 5.00000000E-01 -5.00000000E-01 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 0.00000000E+00 - 1.00000000E+00 1.00000000E+00 1.00000000E+00 - External to domain conductor voltage transformation matrix, MV - 3 Dimension of MV - 1.00000000E+00 -1.00000000E+00 0.00000000E+00 - 5.00000000E-01 5.00000000E-01 -1.00000000E+00 - 0.00000000E+00 0.00000000E+00 1.00000000E+00 - Domain number 1 - 2 # number of conductors - High frequency Per-Unit-length Inductance Matrix, L - 1 Dimension of L - 5.17395547E-07 - High frequency Per-Unit-length Capacitance Matrix, C - 1 Dimension of C - 2.15048247E-11 - Per-Unit-length Impedance Matrix, Z - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 5.1739554748668476E-007 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - Per-Unit-length Admittance Matrix, Y - Matrix of Laplace domain filters - 1 # dimension of Sfilter matrix -Element: 1 1 - 1.0000000000000000 # w normalisation constant - 1 # a order, a coefficients follow below: - 0.0000000000000000 2.1504824721741357E-011 - 0 # b order, b coefficients follow below: - 1.0000000000000000 - # Local reference conductor for internal domains - 2 - 0 - # number of conductors in each domain - 2 - 2 - # External conductor information and dielectric model - 1 conductor type - 3.7500000000000001E-004 conductor_radius - 0.0000000000000000 conductor_width - 0.0000000000000000 conductor_width2 - 0.0000000000000000 conductor_height - 0.0000000000000000 conductor_ox - 5.7499999999999999E-004 dielectric_radius - 0.0000000000000000 dielectric_width - 0.0000000000000000 dielectric_height - 0.0000000000000000 dielectric_ox - 1.0000000000000000 # w normalisation constant - 0 # a order, a coefficients follow below: - 1.0000000000000000 - 0 # b order, b coefficients follow below: - 1.0000000000000000 diff --git a/EXAMPLE_MOD/CABLE/twisted_pair.cable_spec b/EXAMPLE_MOD/CABLE/twisted_pair.cable_spec deleted file mode 100644 index f1e6b75..0000000 --- a/EXAMPLE_MOD/CABLE/twisted_pair.cable_spec +++ /dev/null @@ -1,17 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -Twisted_pair -2 #number of conductors -4 #number of parameters -0.25e-3 # parameter 1: conductor radius (m) -1.0e-3 # parameter 2: conductor separation (m) -4.5e-4 # parameter 3: dielectric radius (m) -0.0 # parameter 4: inner conductor electric conductivity (m) -1 # number of frequency dependent parameters - # Dielectric relative permittivity model follows -1.0 # w normalisation constant -0 # a order, a coefficients follow below -1.00 -0 # b order, b coefficients follow below -1.0 -use_laplace diff --git a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField.spice_model_spec b/EXAMPLE_MOD/SPICE/Coax_Gnd_EField.spice_model_spec deleted file mode 100644 index fae293f..0000000 --- a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField.spice_model_spec +++ /dev/null @@ -1,19 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -# MOD_bundle_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -# MOD_spice_bundle_lib_dir -../MOD_WEB_EXAMPLES/SPICE/ -# spice_symbol_dir -../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ -# Specification for spice model of Coax_Gnd_EField -Coax_Gnd_EField -# cable bundle length (m) -1.22 -# Incident field specification -1.0 amplitude (V/m) -60.0 202.0 ktheta kphi (degrees) -1.0 0.5 Etheta Ephi (degrees) -# Transfer Impedance Model -0 # number of transfer impedances to include in the model -No_validation_test \ No newline at end of file diff --git a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_LTspice.lib b/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_LTspice.lib deleted file mode 100644 index 6b0ecac..0000000 --- a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_LTspice.lib +++ /dev/null @@ -1,288 +0,0 @@ -* LTspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 4 cable number: 1 type:coax name:coaxial_cable_02 conductor number 1 -* node: 5 cable number: 1 type:coax name:coaxial_cable_02 conductor number 2 -* node: 6 Ground plane -* -* End 2 nodes: -* -* node: 7 cable number: 1 type:coax name:coaxial_cable_02 conductor number 1 -* node: 8 cable number: 1 type:coax name:coaxial_cable_02 conductor number 2 -* node: 9 Ground plane -* -* Incident field function nodes: -* -* 2 3 -* -.subckt Coax_Gnd_EField -+ 4 5 6 -+ 7 8 9 -+ 2 3 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 4 10 2.201463E-02 -Rdc_c2_e1 5 11 1.830000E-01 -Rdc_c3_e1 6 1 6.100000E-09 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 7 12 2.201463E-02 -Rdc_c2_e2 8 13 1.830000E-01 -Rdc_c3_e2 9 1 6.100000E-09 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 10 16 -Vmeas_domain_decomp_c2_e1 11 18 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 16 17 14 1 1.000000E+00 -E_domain_decomp_c1_dc2_e1 17 1 15 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 18 19 14 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e1 19 1 15 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 14 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc1_e1 1 14 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 15 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 15 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 12 22 -Vmeas_domain_decomp_c2_e2 13 24 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 22 23 20 1 1.000000E+00 -E_domain_decomp_c1_dc2_e2 23 1 21 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 24 25 20 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e2 25 1 21 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 20 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc1_e2 1 20 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 21 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 21 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 14 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 26 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 20 29 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 29 1 28 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 28 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 26 30 4.848574E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 28 31 4.848574E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 30 1 32 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 31 1 33 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 33 1 34 1 Z0= 4.848574E+01 TD= 6.304414E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 32 1 35 1 Z0= 4.848574E+01 TD= 6.304414E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 33 1 4.848574E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 32 1 4.848574E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 34 36 26 1 2.000000E+00 -E_m_pz_d1_m1_e2 36 1 30 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 35 37 28 1 2.000000E+00 -E_m_mz_d1_m1_e2 37 1 31 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 15 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 38 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 21 41 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 41 1 40 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 40 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 38 44 1.980799E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 40 45 1.980799E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 44 42 46 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 45 43 47 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 47 1 48 1 Z0= 1.980799E+02 TD= 4.069482E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 46 1 49 1 Z0= 1.980799E+02 TD= 4.069482E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 47 1 1.980799E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 46 1 1.980799E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 48 50 38 1 2.000000E+00 -E_m_pz_d2_m1_e2 50 1 44 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 49 51 40 1 2.000000E+00 -E_m_mz_d2_m1_e2 51 1 45 1 -1.000000E+00 -* -* START OF INCIDENT FIELD EXCITATION MODELS -* -* -* Incident field delay lines, Tz delay -* -T_Tz_Einc 53 1 54 1 Z0= 0.500000E+02 TD= 0.203474E-08 -* -* Matched impedance: Tz delay -* -RZC_Tz_Einc 54 1 0.500000E+02 -* -* Delay line controlled sources Tz delay -* -E1_Tz_Einc 53 1 2 3 0.100000E+01 -* -* Delay line Tz+T_victim(v_mode) -* -T_TzPTv_EINC_vm_1 55 1 56 1 Z0= 0.500000E+02 TD= 0.610422E-08 -* -* Matched impedance: Tz+T_victim(v_mode) delay -* -RZC_TzPTv_EINC_vm_1 56 1 0.500000E+02 -* -* Incident field delay line controlled source: Tz+T_victim(v_mode) delay -* -E1_TzPTv_EINC_vm_1 55 1 2 3 0.100000E+01 -* -* Incident field delay line T_victim(v_mode) -* -T_Tv_EINC_vm_1 57 1 58 1 Z0= 0.500000E+02 TD= 0.406948E-08 -* -* Matched impedance T_victim(v_mode) delay -* -RZC_Tv_EINC_vm_1 58 1 0.500000E+02 -* -* Controlled source for T_victim(v_mode) delay -* -E1_Tv_EINC_vm_1 57 1 2 3 0.100000E+01 -* -* Circuit to combine incident field excitation terms -* -E_zt_dsum_s_EINC_vm_1_E1 59 1 2 3 0.299883E-01 -E_zt_dsum_s_EINC_vm_1_E2 60 59 56 1 -0.299883E-01 -E_zt_dsum_l_EINC_vm_1_E1 61 1 58 1 -0.318364E-02 -E_zt_dsum_l_EINC_vm_1_E2 62 61 54 1 0.318364E-02 -* -* Large resistance to complete the circuit for the series voltage sources -* -R_Einc_dsum_l_EINC_vm_1 62 1 0.100000E+11 -R_Einc_dsum_s_EINC_vm_1 60 1 0.100000E+11 -* -* Incident field excitation sources, end 1 -* -E_Einc_s_EINC_vm_1 42 1 60 1 1.000000E+00 -* -* Incident field excitation sources, end 2 -* -E_Einc_l_EINC_vm_1 43 1 62 1 1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_NGspice.lib b/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_NGspice.lib deleted file mode 100644 index 00ff236..0000000 --- a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_NGspice.lib +++ /dev/null @@ -1,288 +0,0 @@ -* Ngspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 4 cable number: 1 type:coax name:coaxial_cable_02 conductor number 1 -* node: 5 cable number: 1 type:coax name:coaxial_cable_02 conductor number 2 -* node: 6 Ground plane -* -* End 2 nodes: -* -* node: 7 cable number: 1 type:coax name:coaxial_cable_02 conductor number 1 -* node: 8 cable number: 1 type:coax name:coaxial_cable_02 conductor number 2 -* node: 9 Ground plane -* -* Incident field function nodes: -* -* 2 3 -* -.subckt Coax_Gnd_EField -+ 4 5 6 -+ 7 8 9 -+ 2 3 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 4 10 2.201463E-02 -Rdc_c2_e1 5 11 1.830000E-01 -Rdc_c3_e1 6 1 6.100000E-09 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 7 12 2.201463E-02 -Rdc_c2_e2 8 13 1.830000E-01 -Rdc_c3_e2 9 1 6.100000E-09 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 10 16 -Vmeas_domain_decomp_c2_e1 11 18 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 16 17 14 1 1.000000E+00 -E_domain_decomp_c1_dc2_e1 17 1 15 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 18 19 14 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e1 19 1 15 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 14 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc1_e1 1 14 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 15 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 15 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 12 22 -Vmeas_domain_decomp_c2_e2 13 24 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 22 23 20 1 1.000000E+00 -E_domain_decomp_c1_dc2_e2 23 1 21 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 24 25 20 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e2 25 1 21 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 20 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc1_e2 1 20 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 21 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 21 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 14 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 26 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 20 29 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 29 1 28 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 28 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 26 30 4.848574E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 28 31 4.848574E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 30 1 32 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 31 1 33 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 33 1 34 1 Z0= 4.848574E+01 TD= 6.304414E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 32 1 35 1 Z0= 4.848574E+01 TD= 6.304414E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 33 1 4.848574E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 32 1 4.848574E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 34 36 26 1 2.000000E+00 -E_m_pz_d1_m1_e2 36 1 30 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 35 37 28 1 2.000000E+00 -E_m_mz_d1_m1_e2 37 1 31 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 15 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 38 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 21 41 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 41 1 40 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 40 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 38 44 1.980799E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 40 45 1.980799E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 44 42 46 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 45 43 47 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 47 1 48 1 Z0= 1.980799E+02 TD= 4.069482E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 46 1 49 1 Z0= 1.980799E+02 TD= 4.069482E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 47 1 1.980799E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 46 1 1.980799E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 48 50 38 1 2.000000E+00 -E_m_pz_d2_m1_e2 50 1 44 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 49 51 40 1 2.000000E+00 -E_m_mz_d2_m1_e2 51 1 45 1 -1.000000E+00 -* -* START OF INCIDENT FIELD EXCITATION MODELS -* -* -* Incident field delay lines, Tz delay -* -T_Tz_Einc 53 1 54 1 Z0= 0.500000E+02 TD= 0.203474E-08 -* -* Matched impedance: Tz delay -* -RZC_Tz_Einc 54 1 0.500000E+02 -* -* Delay line controlled sources Tz delay -* -E1_Tz_Einc 53 1 2 3 0.100000E+01 -* -* Delay line Tz+T_victim(v_mode) -* -T_TzPTv_EINC_vm_1 55 1 56 1 Z0= 0.500000E+02 TD= 0.610422E-08 -* -* Matched impedance: Tz+T_victim(v_mode) delay -* -RZC_TzPTv_EINC_vm_1 56 1 0.500000E+02 -* -* Incident field delay line controlled source: Tz+T_victim(v_mode) delay -* -E1_TzPTv_EINC_vm_1 55 1 2 3 0.100000E+01 -* -* Incident field delay line T_victim(v_mode) -* -T_Tv_EINC_vm_1 57 1 58 1 Z0= 0.500000E+02 TD= 0.406948E-08 -* -* Matched impedance T_victim(v_mode) delay -* -RZC_Tv_EINC_vm_1 58 1 0.500000E+02 -* -* Controlled source for T_victim(v_mode) delay -* -E1_Tv_EINC_vm_1 57 1 2 3 0.100000E+01 -* -* Circuit to combine incident field excitation terms -* -E_zt_dsum_s_EINC_vm_1_E1 59 1 2 3 0.299883E-01 -E_zt_dsum_s_EINC_vm_1_E2 60 59 56 1 -0.299883E-01 -E_zt_dsum_l_EINC_vm_1_E1 61 1 58 1 -0.318364E-02 -E_zt_dsum_l_EINC_vm_1_E2 62 61 54 1 0.318364E-02 -* -* Large resistance to complete the circuit for the series voltage sources -* -R_Einc_dsum_l_EINC_vm_1 62 1 0.100000E+11 -R_Einc_dsum_s_EINC_vm_1 60 1 0.100000E+11 -* -* Incident field excitation sources, end 1 -* -E_Einc_s_EINC_vm_1 42 1 60 1 1.000000E+00 -* -* Incident field excitation sources, end 2 -* -E_Einc_l_EINC_vm_1 43 1 62 1 1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_Pspice.lib b/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_Pspice.lib deleted file mode 100644 index 0b9c2d8..0000000 --- a/EXAMPLE_MOD/SPICE/Coax_Gnd_EField_Pspice.lib +++ /dev/null @@ -1,288 +0,0 @@ -* Pspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 4 cable number: 1 type:coax name:coaxial_cable_02 conductor number 1 -* node: 5 cable number: 1 type:coax name:coaxial_cable_02 conductor number 2 -* node: 6 Ground plane -* -* End 2 nodes: -* -* node: 7 cable number: 1 type:coax name:coaxial_cable_02 conductor number 1 -* node: 8 cable number: 1 type:coax name:coaxial_cable_02 conductor number 2 -* node: 9 Ground plane -* -* Incident field function nodes: -* -* 2 3 -* -.subckt Coax_Gnd_EField -+ 4 5 6 -+ 7 8 9 -+ 2 3 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 4 10 2.201463E-02 -Rdc_c2_e1 5 11 1.830000E-01 -Rdc_c3_e1 6 1 6.100000E-09 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 7 12 2.201463E-02 -Rdc_c2_e2 8 13 1.830000E-01 -Rdc_c3_e2 9 1 6.100000E-09 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 10 16 -Vmeas_domain_decomp_c2_e1 11 18 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 16 17 14 1 1.000000E+00 -E_domain_decomp_c1_dc2_e1 17 1 15 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 18 19 14 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e1 19 1 15 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 14 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc1_e1 1 14 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 15 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 15 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 12 22 -Vmeas_domain_decomp_c2_e2 13 24 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 22 23 20 1 1.000000E+00 -E_domain_decomp_c1_dc2_e2 23 1 21 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 24 25 20 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e2 25 1 21 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 20 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc1_e2 1 20 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 21 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 21 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 14 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 26 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 20 29 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 29 1 28 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 28 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 26 30 4.848574E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 28 31 4.848574E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 30 1 32 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 31 1 33 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 33 1 34 1 Z0= 4.848574E+01 TD= 6.304414E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 32 1 35 1 Z0= 4.848574E+01 TD= 6.304414E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 33 1 4.848574E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 32 1 4.848574E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 34 36 26 1 2.000000E+00 -E_m_pz_d1_m1_e2 36 1 30 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 35 37 28 1 2.000000E+00 -E_m_mz_d1_m1_e2 37 1 31 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 15 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 38 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 21 41 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 41 1 40 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 40 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 38 44 1.980799E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 40 45 1.980799E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 44 42 46 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 45 43 47 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 47 1 48 1 Z0= 1.980799E+02 TD= 4.069482E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 46 1 49 1 Z0= 1.980799E+02 TD= 4.069482E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 47 1 1.980799E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 46 1 1.980799E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 48 50 38 1 2.000000E+00 -E_m_pz_d2_m1_e2 50 1 44 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 49 51 40 1 2.000000E+00 -E_m_mz_d2_m1_e2 51 1 45 1 -1.000000E+00 -* -* START OF INCIDENT FIELD EXCITATION MODELS -* -* -* Incident field delay lines, Tz delay -* -T_Tz_Einc 53 1 54 1 Z0= 0.500000E+02 TD= 0.203474E-08 -* -* Matched impedance: Tz delay -* -RZC_Tz_Einc 54 1 0.500000E+02 -* -* Delay line controlled sources Tz delay -* -E1_Tz_Einc 53 1 2 3 0.100000E+01 -* -* Delay line Tz+T_victim(v_mode) -* -T_TzPTv_EINC_vm_1 55 1 56 1 Z0= 0.500000E+02 TD= 0.610422E-08 -* -* Matched impedance: Tz+T_victim(v_mode) delay -* -RZC_TzPTv_EINC_vm_1 56 1 0.500000E+02 -* -* Incident field delay line controlled source: Tz+T_victim(v_mode) delay -* -E1_TzPTv_EINC_vm_1 55 1 2 3 0.100000E+01 -* -* Incident field delay line T_victim(v_mode) -* -T_Tv_EINC_vm_1 57 1 58 1 Z0= 0.500000E+02 TD= 0.406948E-08 -* -* Matched impedance T_victim(v_mode) delay -* -RZC_Tv_EINC_vm_1 58 1 0.500000E+02 -* -* Controlled source for T_victim(v_mode) delay -* -E1_Tv_EINC_vm_1 57 1 2 3 0.100000E+01 -* -* Circuit to combine incident field excitation terms -* -E_zt_dsum_s_EINC_vm_1_E1 59 1 2 3 0.299883E-01 -E_zt_dsum_s_EINC_vm_1_E2 60 59 56 1 -0.299883E-01 -E_zt_dsum_l_EINC_vm_1_E1 61 1 58 1 -0.318364E-02 -E_zt_dsum_l_EINC_vm_1_E2 62 61 54 1 0.318364E-02 -* -* Large resistance to complete the circuit for the series voltage sources -* -R_Einc_dsum_l_EINC_vm_1 62 1 0.100000E+11 -R_Einc_dsum_s_EINC_vm_1 60 1 0.100000E+11 -* -* Incident field excitation sources, end 1 -* -E_Einc_s_EINC_vm_1 42 1 60 1 1.000000E+00 -* -* Incident field excitation sources, end 2 -* -E_Einc_l_EINC_vm_1 43 1 62 1 1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/FD_2_Wire.spice_model_spec b/EXAMPLE_MOD/SPICE/FD_2_Wire.spice_model_spec deleted file mode 100644 index d826e63..0000000 --- a/EXAMPLE_MOD/SPICE/FD_2_Wire.spice_model_spec +++ /dev/null @@ -1,19 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -# MOD_bundle_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -# MOD_spice_bundle_lib_dir -../MOD_WEB_EXAMPLES/SPICE/ -# spice_symbol_dir -../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ -# Specification for spice model of FD_2_Wire -FD_2_Wire -# cable bundle length (m) -1.9 -# Incident field specification -0 amplitude (V/m) -0 0 ktheta kphi (degrees) -0 0 Etheta Ephi (degrees) -# Transfer Impedance Model -0 # number of transfer impedances to include in the model -No_validation_test \ No newline at end of file diff --git a/EXAMPLE_MOD/SPICE/FD_2_Wire_LTspice.lib b/EXAMPLE_MOD/SPICE/FD_2_Wire_LTspice.lib deleted file mode 100644 index 2b1823f..0000000 --- a/EXAMPLE_MOD/SPICE/FD_2_Wire_LTspice.lib +++ /dev/null @@ -1,134 +0,0 @@ -* LTspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:cylindrical name:single_wire conductor number 1 -* node: 3 cable number: 2 type:cylindrical name:single_wire conductor number 1 -* -* End 2 nodes: -* -* node: 4 cable number: 1 type:cylindrical name:single_wire conductor number 1 -* node: 5 cable number: 2 type:cylindrical name:single_wire conductor number 1 -* -.subckt FD_2_Wire -+ 2 3 -+ 4 5 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 6 1.666532E-01 -Rdc_c2_e1 3 1 1.666532E-01 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 4 7 1.666532E-01 -Rdc_c2_e2 5 1 1.666532E-01 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 6 9 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 9 1 8 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 8 Vmeas_domain_decomp_c1_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 7 11 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 11 1 10 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 10 Vmeas_domain_decomp_c1_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 8 13 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 13 1 12 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 12 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 10 15 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 15 1 14 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 14 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 12 16 3.305770E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 14 17 3.305770E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 16 1 18 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 17 1 19 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 19 1 20 1 Z0= 3.305770E+02 TD= 6.337718E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 18 1 21 1 Z0= 3.305770E+02 TD= 6.337718E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 19 1 3.305770E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 18 1 3.305770E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 20 22 12 1 2.000000E+00 -E_m_pz_d1_m1_e2 22 1 16 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 21 23 14 1 2.000000E+00 -E_m_mz_d1_m1_e2 23 1 17 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/FD_2_Wire_NGspice.lib b/EXAMPLE_MOD/SPICE/FD_2_Wire_NGspice.lib deleted file mode 100644 index 648c60e..0000000 --- a/EXAMPLE_MOD/SPICE/FD_2_Wire_NGspice.lib +++ /dev/null @@ -1,134 +0,0 @@ -* Ngspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:cylindrical name:single_wire conductor number 1 -* node: 3 cable number: 2 type:cylindrical name:single_wire conductor number 1 -* -* End 2 nodes: -* -* node: 4 cable number: 1 type:cylindrical name:single_wire conductor number 1 -* node: 5 cable number: 2 type:cylindrical name:single_wire conductor number 1 -* -.subckt FD_2_Wire -+ 2 3 -+ 4 5 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 6 1.666532E-01 -Rdc_c2_e1 3 1 1.666532E-01 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 4 7 1.666532E-01 -Rdc_c2_e2 5 1 1.666532E-01 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 6 9 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 9 1 8 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 8 Vmeas_domain_decomp_c1_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 7 11 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 11 1 10 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 10 Vmeas_domain_decomp_c1_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 8 13 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 13 1 12 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 12 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 10 15 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 15 1 14 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 14 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 12 16 3.305770E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 14 17 3.305770E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 16 1 18 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 17 1 19 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 19 1 20 1 Z0= 3.305770E+02 TD= 6.337718E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 18 1 21 1 Z0= 3.305770E+02 TD= 6.337718E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 19 1 3.305770E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 18 1 3.305770E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 20 22 12 1 2.000000E+00 -E_m_pz_d1_m1_e2 22 1 16 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 21 23 14 1 2.000000E+00 -E_m_mz_d1_m1_e2 23 1 17 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/FD_2_Wire_Pspice.lib b/EXAMPLE_MOD/SPICE/FD_2_Wire_Pspice.lib deleted file mode 100644 index 60cb1da..0000000 --- a/EXAMPLE_MOD/SPICE/FD_2_Wire_Pspice.lib +++ /dev/null @@ -1,134 +0,0 @@ -* Pspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:cylindrical name:single_wire conductor number 1 -* node: 3 cable number: 2 type:cylindrical name:single_wire conductor number 1 -* -* End 2 nodes: -* -* node: 4 cable number: 1 type:cylindrical name:single_wire conductor number 1 -* node: 5 cable number: 2 type:cylindrical name:single_wire conductor number 1 -* -.subckt FD_2_Wire -+ 2 3 -+ 4 5 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 6 1.666532E-01 -Rdc_c2_e1 3 1 1.666532E-01 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 4 7 1.666532E-01 -Rdc_c2_e2 5 1 1.666532E-01 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 6 9 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 9 1 8 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 8 Vmeas_domain_decomp_c1_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 7 11 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 11 1 10 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 10 Vmeas_domain_decomp_c1_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 8 13 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 13 1 12 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 12 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 10 15 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 15 1 14 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 14 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 12 16 3.305770E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 14 17 3.305770E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 16 1 18 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 17 1 19 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 19 1 20 1 Z0= 3.305770E+02 TD= 6.337718E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 18 1 21 1 Z0= 3.305770E+02 TD= 6.337718E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 19 1 3.305770E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 18 1 3.305770E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 20 22 12 1 2.000000E+00 -E_m_pz_d1_m1_e2 22 1 16 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 21 23 14 1 2.000000E+00 -E_m_mz_d1_m1_e2 23 1 17 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/Coax_Gnd_EField.asy b/EXAMPLE_MOD/SPICE/SYMBOL/Coax_Gnd_EField.asy deleted file mode 100644 index 1aa908c..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/Coax_Gnd_EField.asy +++ /dev/null @@ -1,34 +0,0 @@ -Version 4 -SymbolType CELL -LINE Normal 16 0 16 96 -LINE Normal 16 96 192 96 -LINE Normal 192 96 192 0 -LINE Normal 192 0 16 0 -LINE Normal 0 16 16 16 -LINE Normal 0 48 16 48 -LINE Normal 0 80 16 80 -LINE Normal 208 16 192 16 -LINE Normal 208 48 192 48 -LINE Normal 208 80 192 80 -WINDOW 3 104 -32 centre 0 -SYMATTR Value Coax_Gnd_EField -SYMATTR Prefix X -SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Coax_Gnd_EField_LTspice.lib -PIN 0 16 LEFT 16 -PINATTR PinName c1_e1 -PINATTR SpiceOrder 1 -PIN 0 48 LEFT 16 -PINATTR PinName c2_e1 -PINATTR SpiceOrder 2 -PIN 0 80 LEFT 16 -PINATTR PinName c3_e1 -PINATTR SpiceOrder 3 -PIN 208 16 RIGHT 16 -PINATTR PinName c1_e2 -PINATTR SpiceOrder 4 -PIN 208 48 RIGHT 16 -PINATTR PinName c2_e2 -PINATTR SpiceOrder 5 -PIN 208 80 RIGHT 16 -PINATTR PinName c3_e2 -PINATTR SpiceOrder 6 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/Coax_Gnd_EField.sym b/EXAMPLE_MOD/SPICE/SYMBOL/Coax_Gnd_EField.sym deleted file mode 100644 index 4e09966..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/Coax_Gnd_EField.sym +++ /dev/null @@ -1,85 +0,0 @@ -v 20050820 1 -L 200 0 200 600 3 0 0 0 -1 -1 -L 200 600 1800 600 3 0 0 0 -1 -1 -L 1800 600 1800 0 3 0 0 0 -1 -1 -L 1800 0 200 0 3 0 0 0 -1 -1 -P 0 500 200 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=1 -T 150 150 5 8 0 0 0 8 1 -pinseq=1 -T 200 500 9 6 1 1 0 1 1 -pinlabel=c1_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 300 200 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=2 -T 150 150 5 8 0 0 0 8 1 -pinseq=2 -T 200 300 9 6 1 1 0 1 1 -pinlabel=c2_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 100 200 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=3 -T 150 150 5 8 0 0 0 8 1 -pinseq=3 -T 200 100 9 6 1 1 0 1 1 -pinlabel=c3_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 500 1800 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=4 -T 150 150 5 8 0 0 0 8 1 -pinseq=4 -T 1800 500 9 6 1 1 0 7 1 -pinlabel=c1_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 300 1800 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=5 -T 150 150 5 8 0 0 0 8 1 -pinseq=5 -T 1800 300 9 6 1 1 0 7 1 -pinlabel=c2_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 100 1800 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=6 -T 150 150 5 8 0 0 0 8 1 -pinseq=6 -T 1800 100 9 6 1 1 0 7 1 -pinlabel=c3_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -T 1000 1000 8 10 1 1 0 4 1 -device=Coax_Gnd_EField -T 1000 800 5 10 1 0 0 4 1 -refdes=X? -T 200 0 8 10 0 0 0 4 1 -description=Coax_Gnd_EField -T 200 0 8 10 0 0 0 0 1 -value=Coax_Gnd_EField -T 200 0 8 10 0 0 0 0 1 -file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Coax_Gnd_EField_NGspice.lib -T 200 0 8 10 0 0 0 0 1 -numslots=0 -T 200 0 8 10 0 0 0 0 1 -symversion=0.1 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/FD_2_Wire.asy b/EXAMPLE_MOD/SPICE/SYMBOL/FD_2_Wire.asy deleted file mode 100644 index 45618fe..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/FD_2_Wire.asy +++ /dev/null @@ -1,26 +0,0 @@ -Version 4 -SymbolType CELL -LINE Normal 16 0 16 64 -LINE Normal 16 64 192 64 -LINE Normal 192 64 192 0 -LINE Normal 192 0 16 0 -LINE Normal 0 16 16 16 -LINE Normal 0 48 16 48 -LINE Normal 208 16 192 16 -LINE Normal 208 48 192 48 -WINDOW 3 104 -32 centre 0 -SYMATTR Value FD_2_Wire -SYMATTR Prefix X -SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/FD_2_Wire_LTspice.lib -PIN 0 16 LEFT 16 -PINATTR PinName c1_e1 -PINATTR SpiceOrder 1 -PIN 0 48 LEFT 16 -PINATTR PinName c2_e1 -PINATTR SpiceOrder 2 -PIN 208 16 RIGHT 16 -PINATTR PinName c1_e2 -PINATTR SpiceOrder 3 -PIN 208 48 RIGHT 16 -PINATTR PinName c2_e2 -PINATTR SpiceOrder 4 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/FD_2_Wire.sym b/EXAMPLE_MOD/SPICE/SYMBOL/FD_2_Wire.sym deleted file mode 100644 index cf618ff..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/FD_2_Wire.sym +++ /dev/null @@ -1,63 +0,0 @@ -v 20050820 1 -L 200 0 200 400 3 0 0 0 -1 -1 -L 200 400 1800 400 3 0 0 0 -1 -1 -L 1800 400 1800 0 3 0 0 0 -1 -1 -L 1800 0 200 0 3 0 0 0 -1 -1 -P 0 300 200 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=1 -T 150 150 5 8 0 0 0 8 1 -pinseq=1 -T 200 300 9 6 1 1 0 1 1 -pinlabel=c1_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 100 200 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=2 -T 150 150 5 8 0 0 0 8 1 -pinseq=2 -T 200 100 9 6 1 1 0 1 1 -pinlabel=c2_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 300 1800 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=3 -T 150 150 5 8 0 0 0 8 1 -pinseq=3 -T 1800 300 9 6 1 1 0 7 1 -pinlabel=c1_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 100 1800 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=4 -T 150 150 5 8 0 0 0 8 1 -pinseq=4 -T 1800 100 9 6 1 1 0 7 1 -pinlabel=c2_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -T 1000 800 8 10 1 1 0 4 1 -device=FD_2_Wire -T 1000 600 5 10 1 0 0 4 1 -refdes=X? -T 200 0 8 10 0 0 0 4 1 -description=FD_2_Wire -T 200 0 8 10 0 0 0 0 1 -value=FD_2_Wire -T 200 0 8 10 0 0 0 0 1 -file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/FD_2_Wire_NGspice.lib -T 200 0 8 10 0 0 0 0 1 -numslots=0 -T 200 0 8 10 0 0 0 0 1 -symversion=0.1 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/Twisted_Pair_Over_Ground.asy b/EXAMPLE_MOD/SPICE/SYMBOL/Twisted_Pair_Over_Ground.asy deleted file mode 100644 index 9f2e3b3..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/Twisted_Pair_Over_Ground.asy +++ /dev/null @@ -1,34 +0,0 @@ -Version 4 -SymbolType CELL -LINE Normal 16 0 16 96 -LINE Normal 16 96 192 96 -LINE Normal 192 96 192 0 -LINE Normal 192 0 16 0 -LINE Normal 0 16 16 16 -LINE Normal 0 48 16 48 -LINE Normal 0 80 16 80 -LINE Normal 208 16 192 16 -LINE Normal 208 48 192 48 -LINE Normal 208 80 192 80 -WINDOW 3 104 -32 centre 0 -SYMATTR Value Twisted_Pair_Over_Ground -SYMATTR Prefix X -SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Twisted_Pair_Over_Ground_LTspice.lib -PIN 0 16 LEFT 16 -PINATTR PinName c1_e1 -PINATTR SpiceOrder 1 -PIN 0 48 LEFT 16 -PINATTR PinName c2_e1 -PINATTR SpiceOrder 2 -PIN 0 80 LEFT 16 -PINATTR PinName c3_e1 -PINATTR SpiceOrder 3 -PIN 208 16 RIGHT 16 -PINATTR PinName c1_e2 -PINATTR SpiceOrder 4 -PIN 208 48 RIGHT 16 -PINATTR PinName c2_e2 -PINATTR SpiceOrder 5 -PIN 208 80 RIGHT 16 -PINATTR PinName c3_e2 -PINATTR SpiceOrder 6 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/Twisted_Pair_Over_Ground.sym b/EXAMPLE_MOD/SPICE/SYMBOL/Twisted_Pair_Over_Ground.sym deleted file mode 100644 index 16623d2..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/Twisted_Pair_Over_Ground.sym +++ /dev/null @@ -1,85 +0,0 @@ -v 20050820 1 -L 200 0 200 600 3 0 0 0 -1 -1 -L 200 600 1800 600 3 0 0 0 -1 -1 -L 1800 600 1800 0 3 0 0 0 -1 -1 -L 1800 0 200 0 3 0 0 0 -1 -1 -P 0 500 200 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=1 -T 150 150 5 8 0 0 0 8 1 -pinseq=1 -T 200 500 9 6 1 1 0 1 1 -pinlabel=c1_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 300 200 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=2 -T 150 150 5 8 0 0 0 8 1 -pinseq=2 -T 200 300 9 6 1 1 0 1 1 -pinlabel=c2_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 100 200 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=3 -T 150 150 5 8 0 0 0 8 1 -pinseq=3 -T 200 100 9 6 1 1 0 1 1 -pinlabel=c3_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 500 1800 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=4 -T 150 150 5 8 0 0 0 8 1 -pinseq=4 -T 1800 500 9 6 1 1 0 7 1 -pinlabel=c1_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 300 1800 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=5 -T 150 150 5 8 0 0 0 8 1 -pinseq=5 -T 1800 300 9 6 1 1 0 7 1 -pinlabel=c2_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 100 1800 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=6 -T 150 150 5 8 0 0 0 8 1 -pinseq=6 -T 1800 100 9 6 1 1 0 7 1 -pinlabel=c3_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -T 1000 1000 8 10 1 1 0 4 1 -device=Twisted_Pair_Over_Ground -T 1000 800 5 10 1 0 0 4 1 -refdes=X? -T 200 0 8 10 0 0 0 4 1 -description=Twisted_Pair_Over_Ground -T 200 0 8 10 0 0 0 0 1 -value=Twisted_Pair_Over_Ground -T 200 0 8 10 0 0 0 0 1 -file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Twisted_Pair_Over_Ground_NGspice.lib -T 200 0 8 10 0 0 0 0 1 -numslots=0 -T 200 0 8 10 0 0 0 0 1 -symversion=0.1 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Coax.asy b/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Coax.asy deleted file mode 100644 index bd09abc..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Coax.asy +++ /dev/null @@ -1,34 +0,0 @@ -Version 4 -SymbolType CELL -LINE Normal 16 0 16 96 -LINE Normal 16 96 192 96 -LINE Normal 192 96 192 0 -LINE Normal 192 0 16 0 -LINE Normal 0 16 16 16 -LINE Normal 0 48 16 48 -LINE Normal 0 80 16 80 -LINE Normal 208 16 192 16 -LINE Normal 208 48 192 48 -LINE Normal 208 80 192 80 -WINDOW 3 104 -32 centre 0 -SYMATTR Value ZT_FD_Coax -SYMATTR Prefix X -SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Coax_LTspice.lib -PIN 0 16 LEFT 16 -PINATTR PinName c1_e1 -PINATTR SpiceOrder 1 -PIN 0 48 LEFT 16 -PINATTR PinName c2_e1 -PINATTR SpiceOrder 2 -PIN 0 80 LEFT 16 -PINATTR PinName c3_e1 -PINATTR SpiceOrder 3 -PIN 208 16 RIGHT 16 -PINATTR PinName c1_e2 -PINATTR SpiceOrder 4 -PIN 208 48 RIGHT 16 -PINATTR PinName c2_e2 -PINATTR SpiceOrder 5 -PIN 208 80 RIGHT 16 -PINATTR PinName c3_e2 -PINATTR SpiceOrder 6 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Coax.sym b/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Coax.sym deleted file mode 100644 index 9b5d046..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Coax.sym +++ /dev/null @@ -1,85 +0,0 @@ -v 20050820 1 -L 200 0 200 600 3 0 0 0 -1 -1 -L 200 600 1800 600 3 0 0 0 -1 -1 -L 1800 600 1800 0 3 0 0 0 -1 -1 -L 1800 0 200 0 3 0 0 0 -1 -1 -P 0 500 200 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=1 -T 150 150 5 8 0 0 0 8 1 -pinseq=1 -T 200 500 9 6 1 1 0 1 1 -pinlabel=c1_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 300 200 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=2 -T 150 150 5 8 0 0 0 8 1 -pinseq=2 -T 200 300 9 6 1 1 0 1 1 -pinlabel=c2_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 100 200 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=3 -T 150 150 5 8 0 0 0 8 1 -pinseq=3 -T 200 100 9 6 1 1 0 1 1 -pinlabel=c3_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 500 1800 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=4 -T 150 150 5 8 0 0 0 8 1 -pinseq=4 -T 1800 500 9 6 1 1 0 7 1 -pinlabel=c1_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 300 1800 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=5 -T 150 150 5 8 0 0 0 8 1 -pinseq=5 -T 1800 300 9 6 1 1 0 7 1 -pinlabel=c2_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 100 1800 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=6 -T 150 150 5 8 0 0 0 8 1 -pinseq=6 -T 1800 100 9 6 1 1 0 7 1 -pinlabel=c3_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -T 1000 1000 8 10 1 1 0 4 1 -device=ZT_FD_Coax -T 1000 800 5 10 1 0 0 4 1 -refdes=X? -T 200 0 8 10 0 0 0 4 1 -description=ZT_FD_Coax -T 200 0 8 10 0 0 0 0 1 -value=ZT_FD_Coax -T 200 0 8 10 0 0 0 0 1 -file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Coax_NGspice.lib -T 200 0 8 10 0 0 0 0 1 -numslots=0 -T 200 0 8 10 0 0 0 0 1 -symversion=0.1 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Spacewire.asy b/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Spacewire.asy deleted file mode 100644 index a6113dd..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Spacewire.asy +++ /dev/null @@ -1,114 +0,0 @@ -Version 4 -SymbolType CELL -LINE Normal 16 0 16 416 -LINE Normal 16 416 192 416 -LINE Normal 192 416 192 0 -LINE Normal 192 0 16 0 -LINE Normal 0 16 16 16 -LINE Normal 0 48 16 48 -LINE Normal 0 80 16 80 -LINE Normal 0 112 16 112 -LINE Normal 0 144 16 144 -LINE Normal 0 176 16 176 -LINE Normal 0 208 16 208 -LINE Normal 0 240 16 240 -LINE Normal 0 272 16 272 -LINE Normal 0 304 16 304 -LINE Normal 0 336 16 336 -LINE Normal 0 368 16 368 -LINE Normal 0 400 16 400 -LINE Normal 208 16 192 16 -LINE Normal 208 48 192 48 -LINE Normal 208 80 192 80 -LINE Normal 208 112 192 112 -LINE Normal 208 144 192 144 -LINE Normal 208 176 192 176 -LINE Normal 208 208 192 208 -LINE Normal 208 240 192 240 -LINE Normal 208 272 192 272 -LINE Normal 208 304 192 304 -LINE Normal 208 336 192 336 -LINE Normal 208 368 192 368 -LINE Normal 208 400 192 400 -WINDOW 3 104 -32 centre 0 -SYMATTR Value ZT_FD_Spacewire -SYMATTR Prefix X -SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Spacewire_LTspice.lib -PIN 0 16 LEFT 16 -PINATTR PinName c1_e1 -PINATTR SpiceOrder 1 -PIN 0 48 LEFT 16 -PINATTR PinName c2_e1 -PINATTR SpiceOrder 2 -PIN 0 80 LEFT 16 -PINATTR PinName c3_e1 -PINATTR SpiceOrder 3 -PIN 0 112 LEFT 16 -PINATTR PinName c4_e1 -PINATTR SpiceOrder 4 -PIN 0 144 LEFT 16 -PINATTR PinName c5_e1 -PINATTR SpiceOrder 5 -PIN 0 176 LEFT 16 -PINATTR PinName c6_e1 -PINATTR SpiceOrder 6 -PIN 0 208 LEFT 16 -PINATTR PinName c7_e1 -PINATTR SpiceOrder 7 -PIN 0 240 LEFT 16 -PINATTR PinName c8_e1 -PINATTR SpiceOrder 8 -PIN 0 272 LEFT 16 -PINATTR PinName c9_e1 -PINATTR SpiceOrder 9 -PIN 0 304 LEFT 16 -PINATTR PinName c10_e1 -PINATTR SpiceOrder 10 -PIN 0 336 LEFT 16 -PINATTR PinName c11_e1 -PINATTR SpiceOrder 11 -PIN 0 368 LEFT 16 -PINATTR PinName c12_e1 -PINATTR SpiceOrder 12 -PIN 0 400 LEFT 16 -PINATTR PinName c13_e1 -PINATTR SpiceOrder 13 -PIN 208 16 RIGHT 16 -PINATTR PinName c1_e2 -PINATTR SpiceOrder 14 -PIN 208 48 RIGHT 16 -PINATTR PinName c2_e2 -PINATTR SpiceOrder 15 -PIN 208 80 RIGHT 16 -PINATTR PinName c3_e2 -PINATTR SpiceOrder 16 -PIN 208 112 RIGHT 16 -PINATTR PinName c4_e2 -PINATTR SpiceOrder 17 -PIN 208 144 RIGHT 16 -PINATTR PinName c5_e2 -PINATTR SpiceOrder 18 -PIN 208 176 RIGHT 16 -PINATTR PinName c6_e2 -PINATTR SpiceOrder 19 -PIN 208 208 RIGHT 16 -PINATTR PinName c7_e2 -PINATTR SpiceOrder 20 -PIN 208 240 RIGHT 16 -PINATTR PinName c8_e2 -PINATTR SpiceOrder 21 -PIN 208 272 RIGHT 16 -PINATTR PinName c9_e2 -PINATTR SpiceOrder 22 -PIN 208 304 RIGHT 16 -PINATTR PinName c10_e2 -PINATTR SpiceOrder 23 -PIN 208 336 RIGHT 16 -PINATTR PinName c11_e2 -PINATTR SpiceOrder 24 -PIN 208 368 RIGHT 16 -PINATTR PinName c12_e2 -PINATTR SpiceOrder 25 -PIN 208 400 RIGHT 16 -PINATTR PinName c13_e2 -PINATTR SpiceOrder 26 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Spacewire.sym b/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Spacewire.sym deleted file mode 100644 index 4bb307e..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Spacewire.sym +++ /dev/null @@ -1,305 +0,0 @@ -v 20050820 1 -L 200 0 200 2600 3 0 0 0 -1 -1 -L 200 2600 1800 2600 3 0 0 0 -1 -1 -L 1800 2600 1800 0 3 0 0 0 -1 -1 -L 1800 0 200 0 3 0 0 0 -1 -1 -P 0 2500 200 2500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=1 -T 150 150 5 8 0 0 0 8 1 -pinseq=1 -T 200 2500 9 6 1 1 0 1 1 -pinlabel=c1_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 2300 200 2300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=2 -T 150 150 5 8 0 0 0 8 1 -pinseq=2 -T 200 2300 9 6 1 1 0 1 1 -pinlabel=c2_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 2100 200 2100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=3 -T 150 150 5 8 0 0 0 8 1 -pinseq=3 -T 200 2100 9 6 1 1 0 1 1 -pinlabel=c3_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 1900 200 1900 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=4 -T 150 150 5 8 0 0 0 8 1 -pinseq=4 -T 200 1900 9 6 1 1 0 1 1 -pinlabel=c4_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 1700 200 1700 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=5 -T 150 150 5 8 0 0 0 8 1 -pinseq=5 -T 200 1700 9 6 1 1 0 1 1 -pinlabel=c5_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 1500 200 1500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=6 -T 150 150 5 8 0 0 0 8 1 -pinseq=6 -T 200 1500 9 6 1 1 0 1 1 -pinlabel=c6_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 1300 200 1300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=7 -T 150 150 5 8 0 0 0 8 1 -pinseq=7 -T 200 1300 9 6 1 1 0 1 1 -pinlabel=c7_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 1100 200 1100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=8 -T 150 150 5 8 0 0 0 8 1 -pinseq=8 -T 200 1100 9 6 1 1 0 1 1 -pinlabel=c8_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 900 200 900 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=9 -T 150 150 5 8 0 0 0 8 1 -pinseq=9 -T 200 900 9 6 1 1 0 1 1 -pinlabel=c9_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 700 200 700 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=10 -T 150 150 5 8 0 0 0 8 1 -pinseq=10 -T 200 700 9 6 1 1 0 1 1 -pinlabel=c10_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 500 200 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=11 -T 150 150 5 8 0 0 0 8 1 -pinseq=11 -T 200 500 9 6 1 1 0 1 1 -pinlabel=c11_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 300 200 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=12 -T 150 150 5 8 0 0 0 8 1 -pinseq=12 -T 200 300 9 6 1 1 0 1 1 -pinlabel=c12_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 100 200 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=13 -T 150 150 5 8 0 0 0 8 1 -pinseq=13 -T 200 100 9 6 1 1 0 1 1 -pinlabel=c13_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 2500 1800 2500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=14 -T 150 150 5 8 0 0 0 8 1 -pinseq=14 -T 1800 2500 9 6 1 1 0 7 1 -pinlabel=c1_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 2300 1800 2300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=15 -T 150 150 5 8 0 0 0 8 1 -pinseq=15 -T 1800 2300 9 6 1 1 0 7 1 -pinlabel=c2_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 2100 1800 2100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=16 -T 150 150 5 8 0 0 0 8 1 -pinseq=16 -T 1800 2100 9 6 1 1 0 7 1 -pinlabel=c3_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 1900 1800 1900 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=17 -T 150 150 5 8 0 0 0 8 1 -pinseq=17 -T 1800 1900 9 6 1 1 0 7 1 -pinlabel=c4_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 1700 1800 1700 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=18 -T 150 150 5 8 0 0 0 8 1 -pinseq=18 -T 1800 1700 9 6 1 1 0 7 1 -pinlabel=c5_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 1500 1800 1500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=19 -T 150 150 5 8 0 0 0 8 1 -pinseq=19 -T 1800 1500 9 6 1 1 0 7 1 -pinlabel=c6_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 1300 1800 1300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=20 -T 150 150 5 8 0 0 0 8 1 -pinseq=20 -T 1800 1300 9 6 1 1 0 7 1 -pinlabel=c7_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 1100 1800 1100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=21 -T 150 150 5 8 0 0 0 8 1 -pinseq=21 -T 1800 1100 9 6 1 1 0 7 1 -pinlabel=c8_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 900 1800 900 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=22 -T 150 150 5 8 0 0 0 8 1 -pinseq=22 -T 1800 900 9 6 1 1 0 7 1 -pinlabel=c9_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 700 1800 700 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=23 -T 150 150 5 8 0 0 0 8 1 -pinseq=23 -T 1800 700 9 6 1 1 0 7 1 -pinlabel=c10_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 500 1800 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=24 -T 150 150 5 8 0 0 0 8 1 -pinseq=24 -T 1800 500 9 6 1 1 0 7 1 -pinlabel=c11_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 300 1800 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=25 -T 150 150 5 8 0 0 0 8 1 -pinseq=25 -T 1800 300 9 6 1 1 0 7 1 -pinlabel=c12_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 100 1800 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=26 -T 150 150 5 8 0 0 0 8 1 -pinseq=26 -T 1800 100 9 6 1 1 0 7 1 -pinlabel=c13_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -T 1000 3000 8 10 1 1 0 4 1 -device=ZT_FD_Spacewire -T 1000 2800 5 10 1 0 0 4 1 -refdes=X? -T 200 0 8 10 0 0 0 4 1 -description=ZT_FD_Spacewire -T 200 0 8 10 0 0 0 0 1 -value=ZT_FD_Spacewire -T 200 0 8 10 0 0 0 0 1 -file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Spacewire_NGspice.lib -T 200 0 8 10 0 0 0 0 1 -numslots=0 -T 200 0 8 10 0 0 0 0 1 -symversion=0.1 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Twinax.asy b/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Twinax.asy deleted file mode 100644 index 83c4a99..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Twinax.asy +++ /dev/null @@ -1,34 +0,0 @@ -Version 4 -SymbolType CELL -LINE Normal 16 0 16 96 -LINE Normal 16 96 192 96 -LINE Normal 192 96 192 0 -LINE Normal 192 0 16 0 -LINE Normal 0 16 16 16 -LINE Normal 0 48 16 48 -LINE Normal 0 80 16 80 -LINE Normal 208 16 192 16 -LINE Normal 208 48 192 48 -LINE Normal 208 80 192 80 -WINDOW 3 104 -32 centre 0 -SYMATTR Value ZT_FD_Twinax -SYMATTR Prefix X -SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Twinax_LTspice.lib -PIN 0 16 LEFT 16 -PINATTR PinName c1_e1 -PINATTR SpiceOrder 1 -PIN 0 48 LEFT 16 -PINATTR PinName c2_e1 -PINATTR SpiceOrder 2 -PIN 0 80 LEFT 16 -PINATTR PinName c3_e1 -PINATTR SpiceOrder 3 -PIN 208 16 RIGHT 16 -PINATTR PinName c1_e2 -PINATTR SpiceOrder 4 -PIN 208 48 RIGHT 16 -PINATTR PinName c2_e2 -PINATTR SpiceOrder 5 -PIN 208 80 RIGHT 16 -PINATTR PinName c3_e2 -PINATTR SpiceOrder 6 diff --git a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Twinax.sym b/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Twinax.sym deleted file mode 100644 index 97fc2e7..0000000 --- a/EXAMPLE_MOD/SPICE/SYMBOL/ZT_FD_Twinax.sym +++ /dev/null @@ -1,85 +0,0 @@ -v 20050820 1 -L 200 0 200 600 3 0 0 0 -1 -1 -L 200 600 1800 600 3 0 0 0 -1 -1 -L 1800 600 1800 0 3 0 0 0 -1 -1 -L 1800 0 200 0 3 0 0 0 -1 -1 -P 0 500 200 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=1 -T 150 150 5 8 0 0 0 8 1 -pinseq=1 -T 200 500 9 6 1 1 0 1 1 -pinlabel=c1_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 300 200 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=2 -T 150 150 5 8 0 0 0 8 1 -pinseq=2 -T 200 300 9 6 1 1 0 1 1 -pinlabel=c2_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 0 100 200 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=3 -T 150 150 5 8 0 0 0 8 1 -pinseq=3 -T 200 100 9 6 1 1 0 1 1 -pinlabel=c3_e1 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 500 1800 500 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=4 -T 150 150 5 8 0 0 0 8 1 -pinseq=4 -T 1800 500 9 6 1 1 0 7 1 -pinlabel=c1_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 300 1800 300 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=5 -T 150 150 5 8 0 0 0 8 1 -pinseq=5 -T 1800 300 9 6 1 1 0 7 1 -pinlabel=c2_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -P 2000 100 1800 100 1 0 0 -{ -T 150 250 5 8 0 0 0 6 1 -pinnumber=6 -T 150 150 5 8 0 0 0 8 1 -pinseq=6 -T 1800 100 9 6 1 1 0 7 1 -pinlabel=c3_e2 -T 200 200 5 8 0 0 0 2 1 -pintype=pas -} -T 1000 1000 8 10 1 1 0 4 1 -device=ZT_FD_Twinax -T 1000 800 5 10 1 0 0 4 1 -refdes=X? -T 200 0 8 10 0 0 0 4 1 -description=ZT_FD_Twinax -T 200 0 8 10 0 0 0 0 1 -value=ZT_FD_Twinax -T 200 0 8 10 0 0 0 0 1 -file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Twinax_NGspice.lib -T 200 0 8 10 0 0 0 0 1 -numslots=0 -T 200 0 8 10 0 0 0 0 1 -symversion=0.1 diff --git a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground.spice_model_spec b/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground.spice_model_spec deleted file mode 100644 index 8168b0b..0000000 --- a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground.spice_model_spec +++ /dev/null @@ -1,19 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -# MOD_bundle_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -# MOD_spice_bundle_lib_dir -../MOD_WEB_EXAMPLES/SPICE/ -# spice_symbol_dir -../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ -# Specification for spice model of Twisted_Pair_Over_Ground -Twisted_Pair_Over_Ground -# cable bundle length (m) -1.0 -# Incident field specification -0 amplitude (V/m) -0 0 ktheta kphi (degrees) -0 0 Etheta Ephi (degrees) -# Transfer Impedance Model -0 # number of transfer impedances to include in the model -No_validation_test \ No newline at end of file diff --git a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_LTspice.lib b/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_LTspice.lib deleted file mode 100644 index 599a0bd..0000000 --- a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_LTspice.lib +++ /dev/null @@ -1,224 +0,0 @@ -* LTspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:twisted_pair name:twisted_pair conductor number 1 -* node: 3 cable number: 1 type:twisted_pair name:twisted_pair conductor number 2 -* node: 4 Ground plane -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:twisted_pair name:twisted_pair conductor number 1 -* node: 6 cable number: 1 type:twisted_pair name:twisted_pair conductor number 2 -* node: 7 Ground plane -* -.subckt Twisted_Pair_Over_Ground -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.000000E-09 -Rdc_c2_e1 3 9 5.000000E-09 -Rdc_c3_e1 4 1 5.000000E-09 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.000000E-09 -Rdc_c2_e2 6 11 5.000000E-09 -Rdc_c3_e2 7 1 5.000000E-09 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 5.000000E-01 -E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 5.000000E-01 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 -5.000000E-01 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 5.000000E-01 -E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 5.000000E-01 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 -5.000000E-01 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 25 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 28 1.551113E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 26 29 1.551113E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 28 1 30 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 29 1 31 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 31 1 32 1 Z0= 1.551113E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 30 1 33 1 Z0= 1.551113E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 31 1 1.551113E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 30 1 1.551113E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 -E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 13 37 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 19 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 36 40 1.915617E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 38 41 1.915617E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 40 1 42 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 41 1 43 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 43 1 44 1 Z0= 1.915617E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 42 1 45 1 Z0= 1.915617E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 43 1 1.915617E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 42 1 1.915617E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 -E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 -E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_NGspice.lib b/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_NGspice.lib deleted file mode 100644 index 3bf0791..0000000 --- a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_NGspice.lib +++ /dev/null @@ -1,224 +0,0 @@ -* Ngspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:twisted_pair name:twisted_pair conductor number 1 -* node: 3 cable number: 1 type:twisted_pair name:twisted_pair conductor number 2 -* node: 4 Ground plane -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:twisted_pair name:twisted_pair conductor number 1 -* node: 6 cable number: 1 type:twisted_pair name:twisted_pair conductor number 2 -* node: 7 Ground plane -* -.subckt Twisted_Pair_Over_Ground -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.000000E-09 -Rdc_c2_e1 3 9 5.000000E-09 -Rdc_c3_e1 4 1 5.000000E-09 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.000000E-09 -Rdc_c2_e2 6 11 5.000000E-09 -Rdc_c3_e2 7 1 5.000000E-09 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 5.000000E-01 -E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 5.000000E-01 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 -5.000000E-01 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 5.000000E-01 -E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 5.000000E-01 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 -5.000000E-01 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 25 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 28 1.551113E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 26 29 1.551113E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 28 1 30 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 29 1 31 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 31 1 32 1 Z0= 1.551113E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 30 1 33 1 Z0= 1.551113E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 31 1 1.551113E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 30 1 1.551113E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 -E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 13 37 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 19 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 36 40 1.915617E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 38 41 1.915617E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 40 1 42 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 41 1 43 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 43 1 44 1 Z0= 1.915617E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 42 1 45 1 Z0= 1.915617E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 43 1 1.915617E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 42 1 1.915617E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 -E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 -E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_Pspice.lib b/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_Pspice.lib deleted file mode 100644 index f67be41..0000000 --- a/EXAMPLE_MOD/SPICE/Twisted_Pair_Over_Ground_Pspice.lib +++ /dev/null @@ -1,224 +0,0 @@ -* Pspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:twisted_pair name:twisted_pair conductor number 1 -* node: 3 cable number: 1 type:twisted_pair name:twisted_pair conductor number 2 -* node: 4 Ground plane -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:twisted_pair name:twisted_pair conductor number 1 -* node: 6 cable number: 1 type:twisted_pair name:twisted_pair conductor number 2 -* node: 7 Ground plane -* -.subckt Twisted_Pair_Over_Ground -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.000000E-09 -Rdc_c2_e1 3 9 5.000000E-09 -Rdc_c3_e1 4 1 5.000000E-09 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.000000E-09 -Rdc_c2_e2 6 11 5.000000E-09 -Rdc_c3_e2 7 1 5.000000E-09 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 5.000000E-01 -E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 5.000000E-01 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 -5.000000E-01 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 5.000000E-01 -E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 5.000000E-01 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 -5.000000E-01 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 25 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 28 1.551113E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 26 29 1.551113E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 28 1 30 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 29 1 31 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 31 1 32 1 Z0= 1.551113E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 30 1 33 1 Z0= 1.551113E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 31 1 1.551113E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 30 1 1.551113E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 -E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 13 37 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 19 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 36 40 1.915617E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 38 41 1.915617E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 40 1 42 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 41 1 43 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 43 1 44 1 Z0= 1.915617E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 42 1 45 1 Z0= 1.915617E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 43 1 1.915617E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 42 1 1.915617E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 -E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 -E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Coax.spice_model_spec b/EXAMPLE_MOD/SPICE/ZT_FD_Coax.spice_model_spec deleted file mode 100644 index 60d353b..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Coax.spice_model_spec +++ /dev/null @@ -1,19 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -# MOD_bundle_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -# MOD_spice_bundle_lib_dir -../MOD_WEB_EXAMPLES/SPICE/ -# spice_symbol_dir -../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ -# Specification for spice model of ZT_FD_Coax -ZT_FD_Coax -# cable bundle length (m) -1.0 -# Incident field specification -0 amplitude (V/m) -0 0 ktheta kphi (degrees) -0 0 Etheta Ephi (degrees) -# Transfer Impedance Model -0 # number of transfer impedances to include in the model -No_validation_test \ No newline at end of file diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Coax_LTspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Coax_LTspice.lib deleted file mode 100644 index 88aee1d..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Coax_LTspice.lib +++ /dev/null @@ -1,224 +0,0 @@ -* LTspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:cylindrical name:bare_wire conductor number 1 -* node: 3 cable number: 2 type:coax name:coaxial_cable_01 conductor number 1 -* node: 4 cable number: 2 type:coax name:coaxial_cable_01 conductor number 2 -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:cylindrical name:bare_wire conductor number 1 -* node: 6 cable number: 2 type:coax name:coaxial_cable_01 conductor number 1 -* node: 7 cable number: 2 type:coax name:coaxial_cable_01 conductor number 2 -* -.subckt ZT_FD_Coax -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.000000E-09 -Rdc_c2_e1 3 9 1.804478E-02 -Rdc_c3_e1 4 1 5.000000E-02 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.000000E-09 -Rdc_c2_e2 6 11 1.804478E-02 -Rdc_c3_e2 7 1 5.000000E-02 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 -0.000000E+00 -E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 1.000000E+00 -E_domain_decomp_c2_dc2_e1 17 1 13 1 -0.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 0.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 -0.000000E+00 -E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 1.000000E+00 -E_domain_decomp_c2_dc2_e2 23 1 19 1 -0.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 0.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 25 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 28 4.848574E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 26 29 4.848574E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 28 1 30 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 29 1 31 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 31 1 32 1 Z0= 4.848574E+01 TD= 5.167553E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 30 1 33 1 Z0= 4.848574E+01 TD= 5.167553E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 31 1 4.848574E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 30 1 4.848574E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 -E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 13 37 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 19 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 36 40 3.910788E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 38 41 3.910788E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 40 1 42 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 41 1 43 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 43 1 44 1 Z0= 3.910788E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 42 1 45 1 Z0= 3.910788E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 43 1 3.910788E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 42 1 3.910788E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 -E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 -E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Coax_NGspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Coax_NGspice.lib deleted file mode 100644 index 52dd331..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Coax_NGspice.lib +++ /dev/null @@ -1,224 +0,0 @@ -* Ngspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:cylindrical name:bare_wire conductor number 1 -* node: 3 cable number: 2 type:coax name:coaxial_cable_01 conductor number 1 -* node: 4 cable number: 2 type:coax name:coaxial_cable_01 conductor number 2 -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:cylindrical name:bare_wire conductor number 1 -* node: 6 cable number: 2 type:coax name:coaxial_cable_01 conductor number 1 -* node: 7 cable number: 2 type:coax name:coaxial_cable_01 conductor number 2 -* -.subckt ZT_FD_Coax -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.000000E-09 -Rdc_c2_e1 3 9 1.804478E-02 -Rdc_c3_e1 4 1 5.000000E-02 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.000000E-09 -Rdc_c2_e2 6 11 1.804478E-02 -Rdc_c3_e2 7 1 5.000000E-02 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 -0.000000E+00 -E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 1.000000E+00 -E_domain_decomp_c2_dc2_e1 17 1 13 1 -0.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 0.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 -0.000000E+00 -E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 1.000000E+00 -E_domain_decomp_c2_dc2_e2 23 1 19 1 -0.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 0.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 25 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 28 4.848574E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 26 29 4.848574E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 28 1 30 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 29 1 31 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 31 1 32 1 Z0= 4.848574E+01 TD= 5.167553E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 30 1 33 1 Z0= 4.848574E+01 TD= 5.167553E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 31 1 4.848574E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 30 1 4.848574E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 -E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 13 37 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 19 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 36 40 3.910788E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 38 41 3.910788E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 40 1 42 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 41 1 43 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 43 1 44 1 Z0= 3.910788E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 42 1 45 1 Z0= 3.910788E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 43 1 3.910788E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 42 1 3.910788E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 -E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 -E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Coax_Pspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Coax_Pspice.lib deleted file mode 100644 index 0f6528e..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Coax_Pspice.lib +++ /dev/null @@ -1,224 +0,0 @@ -* Pspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:cylindrical name:bare_wire conductor number 1 -* node: 3 cable number: 2 type:coax name:coaxial_cable_01 conductor number 1 -* node: 4 cable number: 2 type:coax name:coaxial_cable_01 conductor number 2 -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:cylindrical name:bare_wire conductor number 1 -* node: 6 cable number: 2 type:coax name:coaxial_cable_01 conductor number 1 -* node: 7 cable number: 2 type:coax name:coaxial_cable_01 conductor number 2 -* -.subckt ZT_FD_Coax -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.000000E-09 -Rdc_c2_e1 3 9 1.804478E-02 -Rdc_c3_e1 4 1 5.000000E-02 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.000000E-09 -Rdc_c2_e2 6 11 1.804478E-02 -Rdc_c3_e2 7 1 5.000000E-02 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 -0.000000E+00 -E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 1.000000E+00 -E_domain_decomp_c2_dc2_e1 17 1 13 1 -0.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 0.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 -0.000000E+00 -E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 1.000000E+00 -E_domain_decomp_c2_dc2_e2 23 1 19 1 -0.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 0.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 25 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 27 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 28 4.848574E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 26 29 4.848574E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 28 1 30 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 29 1 31 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 31 1 32 1 Z0= 4.848574E+01 TD= 5.167553E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 30 1 33 1 Z0= 4.848574E+01 TD= 5.167553E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 31 1 4.848574E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 30 1 4.848574E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 -E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 13 37 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 19 39 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 36 40 3.910788E+02 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 38 41 3.910788E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 40 1 42 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 41 1 43 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 43 1 44 1 Z0= 3.910788E+02 TD= 3.335641E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 42 1 45 1 Z0= 3.910788E+02 TD= 3.335641E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 43 1 3.910788E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 42 1 3.910788E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 -E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 -E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire.spice_model_spec b/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire.spice_model_spec deleted file mode 100644 index 40138bc..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire.spice_model_spec +++ /dev/null @@ -1,19 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -# MOD_bundle_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -# MOD_spice_bundle_lib_dir -../MOD_WEB_EXAMPLES/SPICE/ -# spice_symbol_dir -../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ -# Specification for spice model of ZT_FD_Spacewire -FD_ZT_Spacewire -# cable bundle length (m) -1.0 -# Incident field specification -0 amplitude (V/m) -0 0 ktheta kphi (degrees) -0 0 Etheta Ephi (degrees) -# Transfer Impedance Model -0 # number of transfer impedances to include in the model -No_validation_test \ No newline at end of file diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_LTspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_LTspice.lib deleted file mode 100644 index 2bd61df..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_LTspice.lib +++ /dev/null @@ -1,1540 +0,0 @@ -* LTspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:spacewire name:spacewire conductor number 1 -* node: 3 cable number: 1 type:spacewire name:spacewire conductor number 2 -* node: 4 cable number: 1 type:spacewire name:spacewire conductor number 3 -* node: 5 cable number: 1 type:spacewire name:spacewire conductor number 4 -* node: 6 cable number: 1 type:spacewire name:spacewire conductor number 5 -* node: 7 cable number: 1 type:spacewire name:spacewire conductor number 6 -* node: 8 cable number: 1 type:spacewire name:spacewire conductor number 7 -* node: 9 cable number: 1 type:spacewire name:spacewire conductor number 8 -* node: 10 cable number: 1 type:spacewire name:spacewire conductor number 9 -* node: 11 cable number: 1 type:spacewire name:spacewire conductor number 10 -* node: 12 cable number: 1 type:spacewire name:spacewire conductor number 11 -* node: 13 cable number: 1 type:spacewire name:spacewire conductor number 12 -* node: 14 cable number: 1 type:spacewire name:spacewire conductor number 13 -* -* End 2 nodes: -* -* node: 15 cable number: 1 type:spacewire name:spacewire conductor number 1 -* node: 16 cable number: 1 type:spacewire name:spacewire conductor number 2 -* node: 17 cable number: 1 type:spacewire name:spacewire conductor number 3 -* node: 18 cable number: 1 type:spacewire name:spacewire conductor number 4 -* node: 19 cable number: 1 type:spacewire name:spacewire conductor number 5 -* node: 20 cable number: 1 type:spacewire name:spacewire conductor number 6 -* node: 21 cable number: 1 type:spacewire name:spacewire conductor number 7 -* node: 22 cable number: 1 type:spacewire name:spacewire conductor number 8 -* node: 23 cable number: 1 type:spacewire name:spacewire conductor number 9 -* node: 24 cable number: 1 type:spacewire name:spacewire conductor number 10 -* node: 25 cable number: 1 type:spacewire name:spacewire conductor number 11 -* node: 26 cable number: 1 type:spacewire name:spacewire conductor number 12 -* node: 27 cable number: 1 type:spacewire name:spacewire conductor number 13 -* -.subckt ZT_FD_Spacewire -+ 2 3 4 5 6 7 8 9 10 11 12 13 14 -+ 15 16 17 18 19 20 21 22 23 24 25 26 27 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 28 5.092958E-02 -Rdc_c2_e1 3 29 5.092958E-02 -Rdc_c3_e1 4 30 5.092958E-02 -Rdc_c4_e1 5 31 5.092958E-02 -Rdc_c5_e1 6 32 5.092958E-02 -Rdc_c6_e1 7 33 5.092958E-02 -Rdc_c7_e1 8 34 5.092958E-02 -Rdc_c8_e1 9 35 5.092958E-02 -Rdc_c9_e1 10 36 1.273240E-02 -Rdc_c10_e1 11 37 1.273240E-02 -Rdc_c11_e1 12 38 1.273240E-02 -Rdc_c12_e1 13 39 1.273240E-02 -Rdc_c13_e1 14 1 3.395291E-03 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 15 40 5.092958E-02 -Rdc_c2_e2 16 41 5.092958E-02 -Rdc_c3_e2 17 42 5.092958E-02 -Rdc_c4_e2 18 43 5.092958E-02 -Rdc_c5_e2 19 44 5.092958E-02 -Rdc_c6_e2 20 45 5.092958E-02 -Rdc_c7_e2 21 46 5.092958E-02 -Rdc_c8_e2 22 47 5.092958E-02 -Rdc_c9_e2 23 48 1.273240E-02 -Rdc_c10_e2 24 49 1.273240E-02 -Rdc_c11_e2 25 50 1.273240E-02 -Rdc_c12_e2 26 51 1.273240E-02 -Rdc_c13_e2 27 1 3.395291E-03 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 28 64 -Vmeas_domain_decomp_c2_e1 29 76 -Vmeas_domain_decomp_c3_e1 30 88 -Vmeas_domain_decomp_c4_e1 31 100 -Vmeas_domain_decomp_c5_e1 32 112 -Vmeas_domain_decomp_c6_e1 33 124 -Vmeas_domain_decomp_c7_e1 34 136 -Vmeas_domain_decomp_c8_e1 35 148 -Vmeas_domain_decomp_c9_e1 36 160 -Vmeas_domain_decomp_c10_e1 37 172 -Vmeas_domain_decomp_c11_e1 38 184 -Vmeas_domain_decomp_c12_e1 39 196 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 64 65 52 1 5.000000E-01 -E_domain_decomp_c1_dc2_e1 65 66 53 1 1.000000E+00 -E_domain_decomp_c1_dc3_e1 66 67 54 1 0.000000E+00 -E_domain_decomp_c1_dc4_e1 67 68 55 1 0.000000E+00 -E_domain_decomp_c1_dc5_e1 68 69 56 1 0.000000E+00 -E_domain_decomp_c1_dc6_e1 69 70 57 1 0.000000E+00 -E_domain_decomp_c1_dc7_e1 70 71 58 1 0.000000E+00 -E_domain_decomp_c1_dc8_e1 71 72 59 1 -0.000000E+00 -E_domain_decomp_c1_dc9_e1 72 73 60 1 1.000000E+00 -E_domain_decomp_c1_dc10_e1 73 74 61 1 0.000000E+00 -E_domain_decomp_c1_dc11_e1 74 75 62 1 0.000000E+00 -E_domain_decomp_c1_dc12_e1 75 1 63 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e1 76 77 52 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e1 77 78 53 1 1.000000E+00 -E_domain_decomp_c2_dc3_e1 78 79 54 1 0.000000E+00 -E_domain_decomp_c2_dc4_e1 79 80 55 1 0.000000E+00 -E_domain_decomp_c2_dc5_e1 80 81 56 1 0.000000E+00 -E_domain_decomp_c2_dc6_e1 81 82 57 1 0.000000E+00 -E_domain_decomp_c2_dc7_e1 82 83 58 1 0.000000E+00 -E_domain_decomp_c2_dc8_e1 83 84 59 1 -0.000000E+00 -E_domain_decomp_c2_dc9_e1 84 85 60 1 1.000000E+00 -E_domain_decomp_c2_dc10_e1 85 86 61 1 0.000000E+00 -E_domain_decomp_c2_dc11_e1 86 87 62 1 0.000000E+00 -E_domain_decomp_c2_dc12_e1 87 1 63 1 -0.000000E+00 -E_domain_decomp_c3_dc1_e1 88 89 52 1 0.000000E+00 -E_domain_decomp_c3_dc2_e1 89 90 53 1 0.000000E+00 -E_domain_decomp_c3_dc3_e1 90 91 54 1 5.000000E-01 -E_domain_decomp_c3_dc4_e1 91 92 55 1 1.000000E+00 -E_domain_decomp_c3_dc5_e1 92 93 56 1 0.000000E+00 -E_domain_decomp_c3_dc6_e1 93 94 57 1 0.000000E+00 -E_domain_decomp_c3_dc7_e1 94 95 58 1 0.000000E+00 -E_domain_decomp_c3_dc8_e1 95 96 59 1 0.000000E+00 -E_domain_decomp_c3_dc9_e1 96 97 60 1 -0.000000E+00 -E_domain_decomp_c3_dc10_e1 97 98 61 1 1.000000E+00 -E_domain_decomp_c3_dc11_e1 98 99 62 1 0.000000E+00 -E_domain_decomp_c3_dc12_e1 99 1 63 1 -0.000000E+00 -E_domain_decomp_c4_dc1_e1 100 101 52 1 0.000000E+00 -E_domain_decomp_c4_dc2_e1 101 102 53 1 0.000000E+00 -E_domain_decomp_c4_dc3_e1 102 103 54 1 -5.000000E-01 -E_domain_decomp_c4_dc4_e1 103 104 55 1 1.000000E+00 -E_domain_decomp_c4_dc5_e1 104 105 56 1 0.000000E+00 -E_domain_decomp_c4_dc6_e1 105 106 57 1 0.000000E+00 -E_domain_decomp_c4_dc7_e1 106 107 58 1 0.000000E+00 -E_domain_decomp_c4_dc8_e1 107 108 59 1 0.000000E+00 -E_domain_decomp_c4_dc9_e1 108 109 60 1 -0.000000E+00 -E_domain_decomp_c4_dc10_e1 109 110 61 1 1.000000E+00 -E_domain_decomp_c4_dc11_e1 110 111 62 1 0.000000E+00 -E_domain_decomp_c4_dc12_e1 111 1 63 1 -0.000000E+00 -E_domain_decomp_c5_dc1_e1 112 113 52 1 0.000000E+00 -E_domain_decomp_c5_dc2_e1 113 114 53 1 0.000000E+00 -E_domain_decomp_c5_dc3_e1 114 115 54 1 0.000000E+00 -E_domain_decomp_c5_dc4_e1 115 116 55 1 0.000000E+00 -E_domain_decomp_c5_dc5_e1 116 117 56 1 5.000000E-01 -E_domain_decomp_c5_dc6_e1 117 118 57 1 1.000000E+00 -E_domain_decomp_c5_dc7_e1 118 119 58 1 0.000000E+00 -E_domain_decomp_c5_dc8_e1 119 120 59 1 0.000000E+00 -E_domain_decomp_c5_dc9_e1 120 121 60 1 0.000000E+00 -E_domain_decomp_c5_dc10_e1 121 122 61 1 -0.000000E+00 -E_domain_decomp_c5_dc11_e1 122 123 62 1 1.000000E+00 -E_domain_decomp_c5_dc12_e1 123 1 63 1 -0.000000E+00 -E_domain_decomp_c6_dc1_e1 124 125 52 1 0.000000E+00 -E_domain_decomp_c6_dc2_e1 125 126 53 1 0.000000E+00 -E_domain_decomp_c6_dc3_e1 126 127 54 1 0.000000E+00 -E_domain_decomp_c6_dc4_e1 127 128 55 1 0.000000E+00 -E_domain_decomp_c6_dc5_e1 128 129 56 1 -5.000000E-01 -E_domain_decomp_c6_dc6_e1 129 130 57 1 1.000000E+00 -E_domain_decomp_c6_dc7_e1 130 131 58 1 0.000000E+00 -E_domain_decomp_c6_dc8_e1 131 132 59 1 0.000000E+00 -E_domain_decomp_c6_dc9_e1 132 133 60 1 0.000000E+00 -E_domain_decomp_c6_dc10_e1 133 134 61 1 -0.000000E+00 -E_domain_decomp_c6_dc11_e1 134 135 62 1 1.000000E+00 -E_domain_decomp_c6_dc12_e1 135 1 63 1 -0.000000E+00 -E_domain_decomp_c7_dc1_e1 136 137 52 1 0.000000E+00 -E_domain_decomp_c7_dc2_e1 137 138 53 1 0.000000E+00 -E_domain_decomp_c7_dc3_e1 138 139 54 1 0.000000E+00 -E_domain_decomp_c7_dc4_e1 139 140 55 1 0.000000E+00 -E_domain_decomp_c7_dc5_e1 140 141 56 1 0.000000E+00 -E_domain_decomp_c7_dc6_e1 141 142 57 1 0.000000E+00 -E_domain_decomp_c7_dc7_e1 142 143 58 1 5.000000E-01 -E_domain_decomp_c7_dc8_e1 143 144 59 1 1.000000E+00 -E_domain_decomp_c7_dc9_e1 144 145 60 1 0.000000E+00 -E_domain_decomp_c7_dc10_e1 145 146 61 1 0.000000E+00 -E_domain_decomp_c7_dc11_e1 146 147 62 1 -0.000000E+00 -E_domain_decomp_c7_dc12_e1 147 1 63 1 1.000000E+00 -E_domain_decomp_c8_dc1_e1 148 149 52 1 0.000000E+00 -E_domain_decomp_c8_dc2_e1 149 150 53 1 0.000000E+00 -E_domain_decomp_c8_dc3_e1 150 151 54 1 0.000000E+00 -E_domain_decomp_c8_dc4_e1 151 152 55 1 0.000000E+00 -E_domain_decomp_c8_dc5_e1 152 153 56 1 0.000000E+00 -E_domain_decomp_c8_dc6_e1 153 154 57 1 0.000000E+00 -E_domain_decomp_c8_dc7_e1 154 155 58 1 -5.000000E-01 -E_domain_decomp_c8_dc8_e1 155 156 59 1 1.000000E+00 -E_domain_decomp_c8_dc9_e1 156 157 60 1 0.000000E+00 -E_domain_decomp_c8_dc10_e1 157 158 61 1 0.000000E+00 -E_domain_decomp_c8_dc11_e1 158 159 62 1 -0.000000E+00 -E_domain_decomp_c8_dc12_e1 159 1 63 1 1.000000E+00 -E_domain_decomp_c9_dc1_e1 160 161 52 1 0.000000E+00 -E_domain_decomp_c9_dc2_e1 161 162 53 1 0.000000E+00 -E_domain_decomp_c9_dc3_e1 162 163 54 1 0.000000E+00 -E_domain_decomp_c9_dc4_e1 163 164 55 1 0.000000E+00 -E_domain_decomp_c9_dc5_e1 164 165 56 1 0.000000E+00 -E_domain_decomp_c9_dc6_e1 165 166 57 1 0.000000E+00 -E_domain_decomp_c9_dc7_e1 166 167 58 1 0.000000E+00 -E_domain_decomp_c9_dc8_e1 167 168 59 1 -0.000000E+00 -E_domain_decomp_c9_dc9_e1 168 169 60 1 1.000000E+00 -E_domain_decomp_c9_dc10_e1 169 170 61 1 0.000000E+00 -E_domain_decomp_c9_dc11_e1 170 171 62 1 0.000000E+00 -E_domain_decomp_c9_dc12_e1 171 1 63 1 -0.000000E+00 -E_domain_decomp_c10_dc1_e1 172 173 52 1 0.000000E+00 -E_domain_decomp_c10_dc2_e1 173 174 53 1 0.000000E+00 -E_domain_decomp_c10_dc3_e1 174 175 54 1 0.000000E+00 -E_domain_decomp_c10_dc4_e1 175 176 55 1 0.000000E+00 -E_domain_decomp_c10_dc5_e1 176 177 56 1 0.000000E+00 -E_domain_decomp_c10_dc6_e1 177 178 57 1 0.000000E+00 -E_domain_decomp_c10_dc7_e1 178 179 58 1 0.000000E+00 -E_domain_decomp_c10_dc8_e1 179 180 59 1 0.000000E+00 -E_domain_decomp_c10_dc9_e1 180 181 60 1 -0.000000E+00 -E_domain_decomp_c10_dc10_e1 181 182 61 1 1.000000E+00 -E_domain_decomp_c10_dc11_e1 182 183 62 1 0.000000E+00 -E_domain_decomp_c10_dc12_e1 183 1 63 1 -0.000000E+00 -E_domain_decomp_c11_dc1_e1 184 185 52 1 0.000000E+00 -E_domain_decomp_c11_dc2_e1 185 186 53 1 0.000000E+00 -E_domain_decomp_c11_dc3_e1 186 187 54 1 0.000000E+00 -E_domain_decomp_c11_dc4_e1 187 188 55 1 0.000000E+00 -E_domain_decomp_c11_dc5_e1 188 189 56 1 0.000000E+00 -E_domain_decomp_c11_dc6_e1 189 190 57 1 0.000000E+00 -E_domain_decomp_c11_dc7_e1 190 191 58 1 0.000000E+00 -E_domain_decomp_c11_dc8_e1 191 192 59 1 0.000000E+00 -E_domain_decomp_c11_dc9_e1 192 193 60 1 0.000000E+00 -E_domain_decomp_c11_dc10_e1 193 194 61 1 -0.000000E+00 -E_domain_decomp_c11_dc11_e1 194 195 62 1 1.000000E+00 -E_domain_decomp_c11_dc12_e1 195 1 63 1 -0.000000E+00 -E_domain_decomp_c12_dc1_e1 196 197 52 1 0.000000E+00 -E_domain_decomp_c12_dc2_e1 197 198 53 1 0.000000E+00 -E_domain_decomp_c12_dc3_e1 198 199 54 1 0.000000E+00 -E_domain_decomp_c12_dc4_e1 199 200 55 1 0.000000E+00 -E_domain_decomp_c12_dc5_e1 200 201 56 1 0.000000E+00 -E_domain_decomp_c12_dc6_e1 201 202 57 1 0.000000E+00 -E_domain_decomp_c12_dc7_e1 202 203 58 1 0.000000E+00 -E_domain_decomp_c12_dc8_e1 203 204 59 1 0.000000E+00 -E_domain_decomp_c12_dc9_e1 204 205 60 1 0.000000E+00 -E_domain_decomp_c12_dc10_e1 205 206 61 1 0.000000E+00 -E_domain_decomp_c12_dc11_e1 206 207 62 1 -0.000000E+00 -E_domain_decomp_c12_dc12_e1 207 1 63 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 52 Vmeas_domain_decomp_c1_e1 5.000000E-01 -F_domain_decomp_c2_dc1_e1 1 52 Vmeas_domain_decomp_c2_e1 -5.000000E-01 -F_domain_decomp_c3_dc1_e1 1 52 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc1_e1 1 52 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc1_e1 1 52 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc1_e1 1 52 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc1_e1 1 52 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc1_e1 1 52 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc1_e1 1 52 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc1_e1 1 52 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc1_e1 1 52 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc1_e1 1 52 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 53 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 53 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c3_dc2_e1 1 53 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc2_e1 1 53 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc2_e1 1 53 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc2_e1 1 53 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc2_e1 1 53 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc2_e1 1 53 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc2_e1 1 53 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc2_e1 1 53 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc2_e1 1 53 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc2_e1 1 53 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc3_e1 1 54 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc3_e1 1 54 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc3_e1 1 54 Vmeas_domain_decomp_c3_e1 5.000000E-01 -F_domain_decomp_c4_dc3_e1 1 54 Vmeas_domain_decomp_c4_e1 -5.000000E-01 -F_domain_decomp_c5_dc3_e1 1 54 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc3_e1 1 54 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc3_e1 1 54 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc3_e1 1 54 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc3_e1 1 54 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc3_e1 1 54 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc3_e1 1 54 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc3_e1 1 54 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc4_e1 1 55 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc4_e1 1 55 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc4_e1 1 55 Vmeas_domain_decomp_c3_e1 1.000000E+00 -F_domain_decomp_c4_dc4_e1 1 55 Vmeas_domain_decomp_c4_e1 1.000000E+00 -F_domain_decomp_c5_dc4_e1 1 55 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc4_e1 1 55 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc4_e1 1 55 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc4_e1 1 55 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc4_e1 1 55 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc4_e1 1 55 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc4_e1 1 55 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc4_e1 1 55 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc5_e1 1 56 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc5_e1 1 56 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc5_e1 1 56 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc5_e1 1 56 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc5_e1 1 56 Vmeas_domain_decomp_c5_e1 5.000000E-01 -F_domain_decomp_c6_dc5_e1 1 56 Vmeas_domain_decomp_c6_e1 -5.000000E-01 -F_domain_decomp_c7_dc5_e1 1 56 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc5_e1 1 56 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc5_e1 1 56 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc5_e1 1 56 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc5_e1 1 56 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc5_e1 1 56 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc6_e1 1 57 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc6_e1 1 57 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc6_e1 1 57 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc6_e1 1 57 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc6_e1 1 57 Vmeas_domain_decomp_c5_e1 1.000000E+00 -F_domain_decomp_c6_dc6_e1 1 57 Vmeas_domain_decomp_c6_e1 1.000000E+00 -F_domain_decomp_c7_dc6_e1 1 57 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc6_e1 1 57 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc6_e1 1 57 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc6_e1 1 57 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc6_e1 1 57 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc6_e1 1 57 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc7_e1 1 58 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc7_e1 1 58 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc7_e1 1 58 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc7_e1 1 58 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc7_e1 1 58 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc7_e1 1 58 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc7_e1 1 58 Vmeas_domain_decomp_c7_e1 5.000000E-01 -F_domain_decomp_c8_dc7_e1 1 58 Vmeas_domain_decomp_c8_e1 -5.000000E-01 -F_domain_decomp_c9_dc7_e1 1 58 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc7_e1 1 58 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc7_e1 1 58 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc7_e1 1 58 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc8_e1 1 59 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc8_e1 1 59 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc8_e1 1 59 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc8_e1 1 59 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc8_e1 1 59 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc8_e1 1 59 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc8_e1 1 59 Vmeas_domain_decomp_c7_e1 1.000000E+00 -F_domain_decomp_c8_dc8_e1 1 59 Vmeas_domain_decomp_c8_e1 1.000000E+00 -F_domain_decomp_c9_dc8_e1 1 59 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc8_e1 1 59 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc8_e1 1 59 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc8_e1 1 59 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc9_e1 1 60 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc9_e1 1 60 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c3_dc9_e1 1 60 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc9_e1 1 60 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc9_e1 1 60 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc9_e1 1 60 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc9_e1 1 60 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc9_e1 1 60 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc9_e1 1 60 Vmeas_domain_decomp_c9_e1 1.000000E+00 -F_domain_decomp_c10_dc9_e1 1 60 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc9_e1 1 60 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc9_e1 1 60 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc10_e1 1 61 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc10_e1 1 61 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc10_e1 1 61 Vmeas_domain_decomp_c3_e1 1.000000E+00 -F_domain_decomp_c4_dc10_e1 1 61 Vmeas_domain_decomp_c4_e1 1.000000E+00 -F_domain_decomp_c5_dc10_e1 1 61 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc10_e1 1 61 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc10_e1 1 61 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc10_e1 1 61 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc10_e1 1 61 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc10_e1 1 61 Vmeas_domain_decomp_c10_e1 1.000000E+00 -F_domain_decomp_c11_dc10_e1 1 61 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc10_e1 1 61 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc11_e1 1 62 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc11_e1 1 62 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc11_e1 1 62 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc11_e1 1 62 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc11_e1 1 62 Vmeas_domain_decomp_c5_e1 1.000000E+00 -F_domain_decomp_c6_dc11_e1 1 62 Vmeas_domain_decomp_c6_e1 1.000000E+00 -F_domain_decomp_c7_dc11_e1 1 62 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc11_e1 1 62 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc11_e1 1 62 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc11_e1 1 62 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc11_e1 1 62 Vmeas_domain_decomp_c11_e1 1.000000E+00 -F_domain_decomp_c12_dc11_e1 1 62 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc12_e1 1 63 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc12_e1 1 63 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc12_e1 1 63 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc12_e1 1 63 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc12_e1 1 63 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc12_e1 1 63 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc12_e1 1 63 Vmeas_domain_decomp_c7_e1 1.000000E+00 -F_domain_decomp_c8_dc12_e1 1 63 Vmeas_domain_decomp_c8_e1 1.000000E+00 -F_domain_decomp_c9_dc12_e1 1 63 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc12_e1 1 63 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc12_e1 1 63 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc12_e1 1 63 Vmeas_domain_decomp_c12_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 40 220 -Vmeas_domain_decomp_c2_e2 41 232 -Vmeas_domain_decomp_c3_e2 42 244 -Vmeas_domain_decomp_c4_e2 43 256 -Vmeas_domain_decomp_c5_e2 44 268 -Vmeas_domain_decomp_c6_e2 45 280 -Vmeas_domain_decomp_c7_e2 46 292 -Vmeas_domain_decomp_c8_e2 47 304 -Vmeas_domain_decomp_c9_e2 48 316 -Vmeas_domain_decomp_c10_e2 49 328 -Vmeas_domain_decomp_c11_e2 50 340 -Vmeas_domain_decomp_c12_e2 51 352 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 220 221 208 1 5.000000E-01 -E_domain_decomp_c1_dc2_e2 221 222 209 1 1.000000E+00 -E_domain_decomp_c1_dc3_e2 222 223 210 1 0.000000E+00 -E_domain_decomp_c1_dc4_e2 223 224 211 1 0.000000E+00 -E_domain_decomp_c1_dc5_e2 224 225 212 1 0.000000E+00 -E_domain_decomp_c1_dc6_e2 225 226 213 1 0.000000E+00 -E_domain_decomp_c1_dc7_e2 226 227 214 1 0.000000E+00 -E_domain_decomp_c1_dc8_e2 227 228 215 1 -0.000000E+00 -E_domain_decomp_c1_dc9_e2 228 229 216 1 1.000000E+00 -E_domain_decomp_c1_dc10_e2 229 230 217 1 0.000000E+00 -E_domain_decomp_c1_dc11_e2 230 231 218 1 0.000000E+00 -E_domain_decomp_c1_dc12_e2 231 1 219 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e2 232 233 208 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e2 233 234 209 1 1.000000E+00 -E_domain_decomp_c2_dc3_e2 234 235 210 1 0.000000E+00 -E_domain_decomp_c2_dc4_e2 235 236 211 1 0.000000E+00 -E_domain_decomp_c2_dc5_e2 236 237 212 1 0.000000E+00 -E_domain_decomp_c2_dc6_e2 237 238 213 1 0.000000E+00 -E_domain_decomp_c2_dc7_e2 238 239 214 1 0.000000E+00 -E_domain_decomp_c2_dc8_e2 239 240 215 1 -0.000000E+00 -E_domain_decomp_c2_dc9_e2 240 241 216 1 1.000000E+00 -E_domain_decomp_c2_dc10_e2 241 242 217 1 0.000000E+00 -E_domain_decomp_c2_dc11_e2 242 243 218 1 0.000000E+00 -E_domain_decomp_c2_dc12_e2 243 1 219 1 -0.000000E+00 -E_domain_decomp_c3_dc1_e2 244 245 208 1 0.000000E+00 -E_domain_decomp_c3_dc2_e2 245 246 209 1 0.000000E+00 -E_domain_decomp_c3_dc3_e2 246 247 210 1 5.000000E-01 -E_domain_decomp_c3_dc4_e2 247 248 211 1 1.000000E+00 -E_domain_decomp_c3_dc5_e2 248 249 212 1 0.000000E+00 -E_domain_decomp_c3_dc6_e2 249 250 213 1 0.000000E+00 -E_domain_decomp_c3_dc7_e2 250 251 214 1 0.000000E+00 -E_domain_decomp_c3_dc8_e2 251 252 215 1 0.000000E+00 -E_domain_decomp_c3_dc9_e2 252 253 216 1 -0.000000E+00 -E_domain_decomp_c3_dc10_e2 253 254 217 1 1.000000E+00 -E_domain_decomp_c3_dc11_e2 254 255 218 1 0.000000E+00 -E_domain_decomp_c3_dc12_e2 255 1 219 1 -0.000000E+00 -E_domain_decomp_c4_dc1_e2 256 257 208 1 0.000000E+00 -E_domain_decomp_c4_dc2_e2 257 258 209 1 0.000000E+00 -E_domain_decomp_c4_dc3_e2 258 259 210 1 -5.000000E-01 -E_domain_decomp_c4_dc4_e2 259 260 211 1 1.000000E+00 -E_domain_decomp_c4_dc5_e2 260 261 212 1 0.000000E+00 -E_domain_decomp_c4_dc6_e2 261 262 213 1 0.000000E+00 -E_domain_decomp_c4_dc7_e2 262 263 214 1 0.000000E+00 -E_domain_decomp_c4_dc8_e2 263 264 215 1 0.000000E+00 -E_domain_decomp_c4_dc9_e2 264 265 216 1 -0.000000E+00 -E_domain_decomp_c4_dc10_e2 265 266 217 1 1.000000E+00 -E_domain_decomp_c4_dc11_e2 266 267 218 1 0.000000E+00 -E_domain_decomp_c4_dc12_e2 267 1 219 1 -0.000000E+00 -E_domain_decomp_c5_dc1_e2 268 269 208 1 0.000000E+00 -E_domain_decomp_c5_dc2_e2 269 270 209 1 0.000000E+00 -E_domain_decomp_c5_dc3_e2 270 271 210 1 0.000000E+00 -E_domain_decomp_c5_dc4_e2 271 272 211 1 0.000000E+00 -E_domain_decomp_c5_dc5_e2 272 273 212 1 5.000000E-01 -E_domain_decomp_c5_dc6_e2 273 274 213 1 1.000000E+00 -E_domain_decomp_c5_dc7_e2 274 275 214 1 0.000000E+00 -E_domain_decomp_c5_dc8_e2 275 276 215 1 0.000000E+00 -E_domain_decomp_c5_dc9_e2 276 277 216 1 0.000000E+00 -E_domain_decomp_c5_dc10_e2 277 278 217 1 -0.000000E+00 -E_domain_decomp_c5_dc11_e2 278 279 218 1 1.000000E+00 -E_domain_decomp_c5_dc12_e2 279 1 219 1 -0.000000E+00 -E_domain_decomp_c6_dc1_e2 280 281 208 1 0.000000E+00 -E_domain_decomp_c6_dc2_e2 281 282 209 1 0.000000E+00 -E_domain_decomp_c6_dc3_e2 282 283 210 1 0.000000E+00 -E_domain_decomp_c6_dc4_e2 283 284 211 1 0.000000E+00 -E_domain_decomp_c6_dc5_e2 284 285 212 1 -5.000000E-01 -E_domain_decomp_c6_dc6_e2 285 286 213 1 1.000000E+00 -E_domain_decomp_c6_dc7_e2 286 287 214 1 0.000000E+00 -E_domain_decomp_c6_dc8_e2 287 288 215 1 0.000000E+00 -E_domain_decomp_c6_dc9_e2 288 289 216 1 0.000000E+00 -E_domain_decomp_c6_dc10_e2 289 290 217 1 -0.000000E+00 -E_domain_decomp_c6_dc11_e2 290 291 218 1 1.000000E+00 -E_domain_decomp_c6_dc12_e2 291 1 219 1 -0.000000E+00 -E_domain_decomp_c7_dc1_e2 292 293 208 1 0.000000E+00 -E_domain_decomp_c7_dc2_e2 293 294 209 1 0.000000E+00 -E_domain_decomp_c7_dc3_e2 294 295 210 1 0.000000E+00 -E_domain_decomp_c7_dc4_e2 295 296 211 1 0.000000E+00 -E_domain_decomp_c7_dc5_e2 296 297 212 1 0.000000E+00 -E_domain_decomp_c7_dc6_e2 297 298 213 1 0.000000E+00 -E_domain_decomp_c7_dc7_e2 298 299 214 1 5.000000E-01 -E_domain_decomp_c7_dc8_e2 299 300 215 1 1.000000E+00 -E_domain_decomp_c7_dc9_e2 300 301 216 1 0.000000E+00 -E_domain_decomp_c7_dc10_e2 301 302 217 1 0.000000E+00 -E_domain_decomp_c7_dc11_e2 302 303 218 1 -0.000000E+00 -E_domain_decomp_c7_dc12_e2 303 1 219 1 1.000000E+00 -E_domain_decomp_c8_dc1_e2 304 305 208 1 0.000000E+00 -E_domain_decomp_c8_dc2_e2 305 306 209 1 0.000000E+00 -E_domain_decomp_c8_dc3_e2 306 307 210 1 0.000000E+00 -E_domain_decomp_c8_dc4_e2 307 308 211 1 0.000000E+00 -E_domain_decomp_c8_dc5_e2 308 309 212 1 0.000000E+00 -E_domain_decomp_c8_dc6_e2 309 310 213 1 0.000000E+00 -E_domain_decomp_c8_dc7_e2 310 311 214 1 -5.000000E-01 -E_domain_decomp_c8_dc8_e2 311 312 215 1 1.000000E+00 -E_domain_decomp_c8_dc9_e2 312 313 216 1 0.000000E+00 -E_domain_decomp_c8_dc10_e2 313 314 217 1 0.000000E+00 -E_domain_decomp_c8_dc11_e2 314 315 218 1 -0.000000E+00 -E_domain_decomp_c8_dc12_e2 315 1 219 1 1.000000E+00 -E_domain_decomp_c9_dc1_e2 316 317 208 1 0.000000E+00 -E_domain_decomp_c9_dc2_e2 317 318 209 1 0.000000E+00 -E_domain_decomp_c9_dc3_e2 318 319 210 1 0.000000E+00 -E_domain_decomp_c9_dc4_e2 319 320 211 1 0.000000E+00 -E_domain_decomp_c9_dc5_e2 320 321 212 1 0.000000E+00 -E_domain_decomp_c9_dc6_e2 321 322 213 1 0.000000E+00 -E_domain_decomp_c9_dc7_e2 322 323 214 1 0.000000E+00 -E_domain_decomp_c9_dc8_e2 323 324 215 1 -0.000000E+00 -E_domain_decomp_c9_dc9_e2 324 325 216 1 1.000000E+00 -E_domain_decomp_c9_dc10_e2 325 326 217 1 0.000000E+00 -E_domain_decomp_c9_dc11_e2 326 327 218 1 0.000000E+00 -E_domain_decomp_c9_dc12_e2 327 1 219 1 -0.000000E+00 -E_domain_decomp_c10_dc1_e2 328 329 208 1 0.000000E+00 -E_domain_decomp_c10_dc2_e2 329 330 209 1 0.000000E+00 -E_domain_decomp_c10_dc3_e2 330 331 210 1 0.000000E+00 -E_domain_decomp_c10_dc4_e2 331 332 211 1 0.000000E+00 -E_domain_decomp_c10_dc5_e2 332 333 212 1 0.000000E+00 -E_domain_decomp_c10_dc6_e2 333 334 213 1 0.000000E+00 -E_domain_decomp_c10_dc7_e2 334 335 214 1 0.000000E+00 -E_domain_decomp_c10_dc8_e2 335 336 215 1 0.000000E+00 -E_domain_decomp_c10_dc9_e2 336 337 216 1 -0.000000E+00 -E_domain_decomp_c10_dc10_e2 337 338 217 1 1.000000E+00 -E_domain_decomp_c10_dc11_e2 338 339 218 1 0.000000E+00 -E_domain_decomp_c10_dc12_e2 339 1 219 1 -0.000000E+00 -E_domain_decomp_c11_dc1_e2 340 341 208 1 0.000000E+00 -E_domain_decomp_c11_dc2_e2 341 342 209 1 0.000000E+00 -E_domain_decomp_c11_dc3_e2 342 343 210 1 0.000000E+00 -E_domain_decomp_c11_dc4_e2 343 344 211 1 0.000000E+00 -E_domain_decomp_c11_dc5_e2 344 345 212 1 0.000000E+00 -E_domain_decomp_c11_dc6_e2 345 346 213 1 0.000000E+00 -E_domain_decomp_c11_dc7_e2 346 347 214 1 0.000000E+00 -E_domain_decomp_c11_dc8_e2 347 348 215 1 0.000000E+00 -E_domain_decomp_c11_dc9_e2 348 349 216 1 0.000000E+00 -E_domain_decomp_c11_dc10_e2 349 350 217 1 -0.000000E+00 -E_domain_decomp_c11_dc11_e2 350 351 218 1 1.000000E+00 -E_domain_decomp_c11_dc12_e2 351 1 219 1 -0.000000E+00 -E_domain_decomp_c12_dc1_e2 352 353 208 1 0.000000E+00 -E_domain_decomp_c12_dc2_e2 353 354 209 1 0.000000E+00 -E_domain_decomp_c12_dc3_e2 354 355 210 1 0.000000E+00 -E_domain_decomp_c12_dc4_e2 355 356 211 1 0.000000E+00 -E_domain_decomp_c12_dc5_e2 356 357 212 1 0.000000E+00 -E_domain_decomp_c12_dc6_e2 357 358 213 1 0.000000E+00 -E_domain_decomp_c12_dc7_e2 358 359 214 1 0.000000E+00 -E_domain_decomp_c12_dc8_e2 359 360 215 1 0.000000E+00 -E_domain_decomp_c12_dc9_e2 360 361 216 1 0.000000E+00 -E_domain_decomp_c12_dc10_e2 361 362 217 1 0.000000E+00 -E_domain_decomp_c12_dc11_e2 362 363 218 1 -0.000000E+00 -E_domain_decomp_c12_dc12_e2 363 1 219 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 208 Vmeas_domain_decomp_c1_e2 5.000000E-01 -F_domain_decomp_c2_dc1_e2 1 208 Vmeas_domain_decomp_c2_e2 -5.000000E-01 -F_domain_decomp_c3_dc1_e2 1 208 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc1_e2 1 208 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc1_e2 1 208 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc1_e2 1 208 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc1_e2 1 208 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc1_e2 1 208 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc1_e2 1 208 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc1_e2 1 208 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc1_e2 1 208 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc1_e2 1 208 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 209 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 209 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c3_dc2_e2 1 209 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc2_e2 1 209 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc2_e2 1 209 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc2_e2 1 209 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc2_e2 1 209 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc2_e2 1 209 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc2_e2 1 209 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc2_e2 1 209 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc2_e2 1 209 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc2_e2 1 209 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc3_e2 1 210 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc3_e2 1 210 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc3_e2 1 210 Vmeas_domain_decomp_c3_e2 5.000000E-01 -F_domain_decomp_c4_dc3_e2 1 210 Vmeas_domain_decomp_c4_e2 -5.000000E-01 -F_domain_decomp_c5_dc3_e2 1 210 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc3_e2 1 210 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc3_e2 1 210 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc3_e2 1 210 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc3_e2 1 210 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc3_e2 1 210 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc3_e2 1 210 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc3_e2 1 210 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc4_e2 1 211 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc4_e2 1 211 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc4_e2 1 211 Vmeas_domain_decomp_c3_e2 1.000000E+00 -F_domain_decomp_c4_dc4_e2 1 211 Vmeas_domain_decomp_c4_e2 1.000000E+00 -F_domain_decomp_c5_dc4_e2 1 211 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc4_e2 1 211 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc4_e2 1 211 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc4_e2 1 211 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc4_e2 1 211 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc4_e2 1 211 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc4_e2 1 211 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc4_e2 1 211 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc5_e2 1 212 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc5_e2 1 212 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc5_e2 1 212 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc5_e2 1 212 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc5_e2 1 212 Vmeas_domain_decomp_c5_e2 5.000000E-01 -F_domain_decomp_c6_dc5_e2 1 212 Vmeas_domain_decomp_c6_e2 -5.000000E-01 -F_domain_decomp_c7_dc5_e2 1 212 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc5_e2 1 212 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc5_e2 1 212 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc5_e2 1 212 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc5_e2 1 212 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc5_e2 1 212 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc6_e2 1 213 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc6_e2 1 213 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc6_e2 1 213 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc6_e2 1 213 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc6_e2 1 213 Vmeas_domain_decomp_c5_e2 1.000000E+00 -F_domain_decomp_c6_dc6_e2 1 213 Vmeas_domain_decomp_c6_e2 1.000000E+00 -F_domain_decomp_c7_dc6_e2 1 213 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc6_e2 1 213 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc6_e2 1 213 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc6_e2 1 213 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc6_e2 1 213 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc6_e2 1 213 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc7_e2 1 214 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc7_e2 1 214 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc7_e2 1 214 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc7_e2 1 214 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc7_e2 1 214 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc7_e2 1 214 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc7_e2 1 214 Vmeas_domain_decomp_c7_e2 5.000000E-01 -F_domain_decomp_c8_dc7_e2 1 214 Vmeas_domain_decomp_c8_e2 -5.000000E-01 -F_domain_decomp_c9_dc7_e2 1 214 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc7_e2 1 214 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc7_e2 1 214 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc7_e2 1 214 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc8_e2 1 215 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc8_e2 1 215 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc8_e2 1 215 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc8_e2 1 215 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc8_e2 1 215 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc8_e2 1 215 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc8_e2 1 215 Vmeas_domain_decomp_c7_e2 1.000000E+00 -F_domain_decomp_c8_dc8_e2 1 215 Vmeas_domain_decomp_c8_e2 1.000000E+00 -F_domain_decomp_c9_dc8_e2 1 215 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc8_e2 1 215 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc8_e2 1 215 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc8_e2 1 215 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc9_e2 1 216 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc9_e2 1 216 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c3_dc9_e2 1 216 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc9_e2 1 216 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc9_e2 1 216 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc9_e2 1 216 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc9_e2 1 216 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc9_e2 1 216 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc9_e2 1 216 Vmeas_domain_decomp_c9_e2 1.000000E+00 -F_domain_decomp_c10_dc9_e2 1 216 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc9_e2 1 216 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc9_e2 1 216 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc10_e2 1 217 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc10_e2 1 217 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc10_e2 1 217 Vmeas_domain_decomp_c3_e2 1.000000E+00 -F_domain_decomp_c4_dc10_e2 1 217 Vmeas_domain_decomp_c4_e2 1.000000E+00 -F_domain_decomp_c5_dc10_e2 1 217 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc10_e2 1 217 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc10_e2 1 217 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc10_e2 1 217 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc10_e2 1 217 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc10_e2 1 217 Vmeas_domain_decomp_c10_e2 1.000000E+00 -F_domain_decomp_c11_dc10_e2 1 217 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc10_e2 1 217 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc11_e2 1 218 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc11_e2 1 218 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc11_e2 1 218 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc11_e2 1 218 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc11_e2 1 218 Vmeas_domain_decomp_c5_e2 1.000000E+00 -F_domain_decomp_c6_dc11_e2 1 218 Vmeas_domain_decomp_c6_e2 1.000000E+00 -F_domain_decomp_c7_dc11_e2 1 218 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc11_e2 1 218 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc11_e2 1 218 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc11_e2 1 218 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc11_e2 1 218 Vmeas_domain_decomp_c11_e2 1.000000E+00 -F_domain_decomp_c12_dc11_e2 1 218 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc12_e2 1 219 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc12_e2 1 219 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc12_e2 1 219 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc12_e2 1 219 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc12_e2 1 219 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc12_e2 1 219 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc12_e2 1 219 Vmeas_domain_decomp_c7_e2 1.000000E+00 -F_domain_decomp_c8_dc12_e2 1 219 Vmeas_domain_decomp_c8_e2 1.000000E+00 -F_domain_decomp_c9_dc12_e2 1 219 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc12_e2 1 219 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc12_e2 1 219 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc12_e2 1 219 Vmeas_domain_decomp_c12_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 52 365 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 365 1 364 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 364 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 208 367 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 367 1 366 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 366 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 364 368 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 366 369 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 368 1 370 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 369 1 371 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 371 1 372 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 370 1 373 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 371 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 370 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 372 374 364 1 2.000000E+00 -E_m_pz_d1_m1_e2 374 1 368 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 373 375 366 1 2.000000E+00 -E_m_mz_d1_m1_e2 375 1 369 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 53 377 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 377 1 376 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 376 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 209 379 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 379 1 378 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 378 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 376 380 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 378 381 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 380 1 382 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 381 1 383 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 383 1 384 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 382 1 385 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 383 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 382 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 384 386 376 1 2.000000E+00 -E_m_pz_d2_m1_e2 386 1 380 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 385 387 378 1 2.000000E+00 -E_m_mz_d2_m1_e2 387 1 381 1 -1.000000E+00 -* -* DOMAIN 3 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d3_c1_e1 54 389 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d3_c1_m1_e1 389 1 388 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d3_c1_m1_e1 1 388 Vmeas_mode_decomp_d3_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d3_c1_e2 210 391 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d3_c1_m1_e2 391 1 390 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d3_c1_m1_e2 1 390 Vmeas_mode_decomp_d3_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d3_m1_e1 388 392 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d3_m1_e2 390 393 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d3_m1_e1 392 1 394 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d3_m1_e2 393 1 395 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d3_m1_e1 395 1 396 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d3_m1_e2 394 1 397 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d3_m1_e1 395 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d3_m1_e2 394 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d3_m1_e1 396 398 388 1 2.000000E+00 -E_m_pz_d3_m1_e2 398 1 392 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d3_m1_e1 397 399 390 1 2.000000E+00 -E_m_mz_d3_m1_e2 399 1 393 1 -1.000000E+00 -* -* DOMAIN 4 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d4_c1_e1 55 401 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d4_c1_m1_e1 401 1 400 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d4_c1_m1_e1 1 400 Vmeas_mode_decomp_d4_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d4_c1_e2 211 403 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d4_c1_m1_e2 403 1 402 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d4_c1_m1_e2 1 402 Vmeas_mode_decomp_d4_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d4_m1_e1 400 404 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d4_m1_e2 402 405 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d4_m1_e1 404 1 406 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d4_m1_e2 405 1 407 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d4_m1_e1 407 1 408 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d4_m1_e2 406 1 409 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d4_m1_e1 407 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d4_m1_e2 406 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d4_m1_e1 408 410 400 1 2.000000E+00 -E_m_pz_d4_m1_e2 410 1 404 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d4_m1_e1 409 411 402 1 2.000000E+00 -E_m_mz_d4_m1_e2 411 1 405 1 -1.000000E+00 -* -* DOMAIN 5 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d5_c1_e1 56 413 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d5_c1_m1_e1 413 1 412 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d5_c1_m1_e1 1 412 Vmeas_mode_decomp_d5_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d5_c1_e2 212 415 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d5_c1_m1_e2 415 1 414 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d5_c1_m1_e2 1 414 Vmeas_mode_decomp_d5_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d5_m1_e1 412 416 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d5_m1_e2 414 417 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d5_m1_e1 416 1 418 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d5_m1_e2 417 1 419 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d5_m1_e1 419 1 420 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d5_m1_e2 418 1 421 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d5_m1_e1 419 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d5_m1_e2 418 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d5_m1_e1 420 422 412 1 2.000000E+00 -E_m_pz_d5_m1_e2 422 1 416 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d5_m1_e1 421 423 414 1 2.000000E+00 -E_m_mz_d5_m1_e2 423 1 417 1 -1.000000E+00 -* -* DOMAIN 6 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d6_c1_e1 57 425 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d6_c1_m1_e1 425 1 424 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d6_c1_m1_e1 1 424 Vmeas_mode_decomp_d6_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d6_c1_e2 213 427 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d6_c1_m1_e2 427 1 426 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d6_c1_m1_e2 1 426 Vmeas_mode_decomp_d6_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d6_m1_e1 424 428 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d6_m1_e2 426 429 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d6_m1_e1 428 1 430 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d6_m1_e2 429 1 431 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d6_m1_e1 431 1 432 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d6_m1_e2 430 1 433 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d6_m1_e1 431 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d6_m1_e2 430 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d6_m1_e1 432 434 424 1 2.000000E+00 -E_m_pz_d6_m1_e2 434 1 428 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d6_m1_e1 433 435 426 1 2.000000E+00 -E_m_mz_d6_m1_e2 435 1 429 1 -1.000000E+00 -* -* DOMAIN 7 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d7_c1_e1 58 437 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d7_c1_m1_e1 437 1 436 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d7_c1_m1_e1 1 436 Vmeas_mode_decomp_d7_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d7_c1_e2 214 439 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d7_c1_m1_e2 439 1 438 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d7_c1_m1_e2 1 438 Vmeas_mode_decomp_d7_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d7_m1_e1 436 440 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d7_m1_e2 438 441 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d7_m1_e1 440 1 442 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d7_m1_e2 441 1 443 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d7_m1_e1 443 1 444 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d7_m1_e2 442 1 445 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d7_m1_e1 443 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d7_m1_e2 442 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d7_m1_e1 444 446 436 1 2.000000E+00 -E_m_pz_d7_m1_e2 446 1 440 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d7_m1_e1 445 447 438 1 2.000000E+00 -E_m_mz_d7_m1_e2 447 1 441 1 -1.000000E+00 -* -* DOMAIN 8 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d8_c1_e1 59 449 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d8_c1_m1_e1 449 1 448 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d8_c1_m1_e1 1 448 Vmeas_mode_decomp_d8_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d8_c1_e2 215 451 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d8_c1_m1_e2 451 1 450 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d8_c1_m1_e2 1 450 Vmeas_mode_decomp_d8_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d8_m1_e1 448 452 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d8_m1_e2 450 453 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d8_m1_e1 452 1 454 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d8_m1_e2 453 1 455 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d8_m1_e1 455 1 456 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d8_m1_e2 454 1 457 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d8_m1_e1 455 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d8_m1_e2 454 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d8_m1_e1 456 458 448 1 2.000000E+00 -E_m_pz_d8_m1_e2 458 1 452 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d8_m1_e1 457 459 450 1 2.000000E+00 -E_m_mz_d8_m1_e2 459 1 453 1 -1.000000E+00 -* -* DOMAIN 9 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d9_c1_e1 60 464 -Vmeas_mode_decomp_d9_c2_e1 61 468 -Vmeas_mode_decomp_d9_c3_e1 62 472 -Vmeas_mode_decomp_d9_c4_e1 63 476 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d9_c1_m1_e1 464 465 460 1 4.99997010E-01 -E_mode_decomp_d9_c1_m2_e1 465 466 461 1 6.60299603E-01 -E_mode_decomp_d9_c1_m3_e1 466 467 462 1 -2.52110920E-01 -E_mode_decomp_d9_c1_m4_e1 467 1 463 1 5.00566867E-01 -E_mode_decomp_d9_c2_m1_e1 468 469 460 1 5.00000814E-01 -E_mode_decomp_d9_c2_m2_e1 469 470 461 1 2.52638434E-01 -E_mode_decomp_d9_c2_m3_e1 470 471 462 1 6.60216363E-01 -E_mode_decomp_d9_c2_m4_e1 471 1 463 1 -5.00372583E-01 -E_mode_decomp_d9_c3_m1_e1 472 473 460 1 5.00001652E-01 -E_mode_decomp_d9_c3_m2_e1 473 474 461 1 -6.60745021E-01 -E_mode_decomp_d9_c3_m3_e1 474 475 462 1 2.52713880E-01 -E_mode_decomp_d9_c3_m4_e1 475 1 463 1 4.99437438E-01 -E_mode_decomp_d9_c4_m1_e1 476 477 460 1 5.00000524E-01 -E_mode_decomp_d9_c4_m2_e1 477 478 461 1 -2.52179072E-01 -E_mode_decomp_d9_c4_m3_e1 478 479 462 1 -6.60825366E-01 -E_mode_decomp_d9_c4_m4_e1 479 1 463 1 -4.99622234E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d9_c1_m1_e1 1 460 Vmeas_mode_decomp_d9_c1_e1 4.99997010E-01 -F_mode_decomp_d9_c2_m1_e1 1 460 Vmeas_mode_decomp_d9_c2_e1 5.00000814E-01 -F_mode_decomp_d9_c3_m1_e1 1 460 Vmeas_mode_decomp_d9_c3_e1 5.00001652E-01 -F_mode_decomp_d9_c4_m1_e1 1 460 Vmeas_mode_decomp_d9_c4_e1 5.00000524E-01 -F_mode_decomp_d9_c1_m2_e1 1 461 Vmeas_mode_decomp_d9_c1_e1 6.60299603E-01 -F_mode_decomp_d9_c2_m2_e1 1 461 Vmeas_mode_decomp_d9_c2_e1 2.52638434E-01 -F_mode_decomp_d9_c3_m2_e1 1 461 Vmeas_mode_decomp_d9_c3_e1 -6.60745021E-01 -F_mode_decomp_d9_c4_m2_e1 1 461 Vmeas_mode_decomp_d9_c4_e1 -2.52179072E-01 -F_mode_decomp_d9_c1_m3_e1 1 462 Vmeas_mode_decomp_d9_c1_e1 -2.52110920E-01 -F_mode_decomp_d9_c2_m3_e1 1 462 Vmeas_mode_decomp_d9_c2_e1 6.60216363E-01 -F_mode_decomp_d9_c3_m3_e1 1 462 Vmeas_mode_decomp_d9_c3_e1 2.52713880E-01 -F_mode_decomp_d9_c4_m3_e1 1 462 Vmeas_mode_decomp_d9_c4_e1 -6.60825366E-01 -F_mode_decomp_d9_c1_m4_e1 1 463 Vmeas_mode_decomp_d9_c1_e1 5.00566867E-01 -F_mode_decomp_d9_c2_m4_e1 1 463 Vmeas_mode_decomp_d9_c2_e1 -5.00372583E-01 -F_mode_decomp_d9_c3_m4_e1 1 463 Vmeas_mode_decomp_d9_c3_e1 4.99437438E-01 -F_mode_decomp_d9_c4_m4_e1 1 463 Vmeas_mode_decomp_d9_c4_e1 -4.99622234E-01 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d9_c1_e2 216 484 -Vmeas_mode_decomp_d9_c2_e2 217 488 -Vmeas_mode_decomp_d9_c3_e2 218 492 -Vmeas_mode_decomp_d9_c4_e2 219 496 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d9_c1_m1_e2 484 485 480 1 4.99997010E-01 -E_mode_decomp_d9_c1_m2_e2 485 486 481 1 6.60299603E-01 -E_mode_decomp_d9_c1_m3_e2 486 487 482 1 -2.52110920E-01 -E_mode_decomp_d9_c1_m4_e2 487 1 483 1 5.00566867E-01 -E_mode_decomp_d9_c2_m1_e2 488 489 480 1 5.00000814E-01 -E_mode_decomp_d9_c2_m2_e2 489 490 481 1 2.52638434E-01 -E_mode_decomp_d9_c2_m3_e2 490 491 482 1 6.60216363E-01 -E_mode_decomp_d9_c2_m4_e2 491 1 483 1 -5.00372583E-01 -E_mode_decomp_d9_c3_m1_e2 492 493 480 1 5.00001652E-01 -E_mode_decomp_d9_c3_m2_e2 493 494 481 1 -6.60745021E-01 -E_mode_decomp_d9_c3_m3_e2 494 495 482 1 2.52713880E-01 -E_mode_decomp_d9_c3_m4_e2 495 1 483 1 4.99437438E-01 -E_mode_decomp_d9_c4_m1_e2 496 497 480 1 5.00000524E-01 -E_mode_decomp_d9_c4_m2_e2 497 498 481 1 -2.52179072E-01 -E_mode_decomp_d9_c4_m3_e2 498 499 482 1 -6.60825366E-01 -E_mode_decomp_d9_c4_m4_e2 499 1 483 1 -4.99622234E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d9_c1_m1_e2 1 480 Vmeas_mode_decomp_d9_c1_e2 4.99997010E-01 -F_mode_decomp_d9_c2_m1_e2 1 480 Vmeas_mode_decomp_d9_c2_e2 5.00000814E-01 -F_mode_decomp_d9_c3_m1_e2 1 480 Vmeas_mode_decomp_d9_c3_e2 5.00001652E-01 -F_mode_decomp_d9_c4_m1_e2 1 480 Vmeas_mode_decomp_d9_c4_e2 5.00000524E-01 -F_mode_decomp_d9_c1_m2_e2 1 481 Vmeas_mode_decomp_d9_c1_e2 6.60299603E-01 -F_mode_decomp_d9_c2_m2_e2 1 481 Vmeas_mode_decomp_d9_c2_e2 2.52638434E-01 -F_mode_decomp_d9_c3_m2_e2 1 481 Vmeas_mode_decomp_d9_c3_e2 -6.60745021E-01 -F_mode_decomp_d9_c4_m2_e2 1 481 Vmeas_mode_decomp_d9_c4_e2 -2.52179072E-01 -F_mode_decomp_d9_c1_m3_e2 1 482 Vmeas_mode_decomp_d9_c1_e2 -2.52110920E-01 -F_mode_decomp_d9_c2_m3_e2 1 482 Vmeas_mode_decomp_d9_c2_e2 6.60216363E-01 -F_mode_decomp_d9_c3_m3_e2 1 482 Vmeas_mode_decomp_d9_c3_e2 2.52713880E-01 -F_mode_decomp_d9_c4_m3_e2 1 482 Vmeas_mode_decomp_d9_c4_e2 -6.60825366E-01 -F_mode_decomp_d9_c1_m4_e2 1 483 Vmeas_mode_decomp_d9_c1_e2 5.00566867E-01 -F_mode_decomp_d9_c2_m4_e2 1 483 Vmeas_mode_decomp_d9_c2_e2 -5.00372583E-01 -F_mode_decomp_d9_c3_m4_e2 1 483 Vmeas_mode_decomp_d9_c3_e2 4.99437438E-01 -F_mode_decomp_d9_c4_m4_e2 1 483 Vmeas_mode_decomp_d9_c4_e2 -4.99622234E-01 -* -* Modal impedance: end1 -* -RZCm_d9_m1_e1 460 500 9.322448E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m1_e2 480 501 9.322448E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m1_e1 500 1 502 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m1_e2 501 1 503 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m1_e1 503 1 504 1 Z0= 9.322448E+01 TD= 3.471226E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m1_e2 502 1 505 1 Z0= 9.322448E+01 TD= 3.471226E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m1_e1 503 1 9.322448E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m1_e2 502 1 9.322448E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m1_e1 504 506 460 1 2.000000E+00 -E_m_pz_d9_m1_e2 506 1 500 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m1_e1 505 507 480 1 2.000000E+00 -E_m_mz_d9_m1_e2 507 1 501 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m2_e1 461 508 4.294265E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m2_e2 481 509 4.294265E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m2_e1 508 1 510 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m2_e2 509 1 511 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m2_e1 511 1 512 1 Z0= 4.294265E+01 TD= 3.563291E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m2_e2 510 1 513 1 Z0= 4.294265E+01 TD= 3.563291E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m2_e1 511 1 4.294265E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m2_e2 510 1 4.294265E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m2_e1 512 514 461 1 2.000000E+00 -E_m_pz_d9_m2_e2 514 1 508 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m2_e1 513 515 481 1 2.000000E+00 -E_m_mz_d9_m2_e2 515 1 509 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m3_e1 462 516 4.294177E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m3_e2 482 517 4.294177E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m3_e1 516 1 518 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m3_e2 517 1 519 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m3_e1 519 1 520 1 Z0= 4.294177E+01 TD= 3.563298E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m3_e2 518 1 521 1 Z0= 4.294177E+01 TD= 3.563298E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m3_e1 519 1 4.294177E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m3_e2 518 1 4.294177E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m3_e1 520 522 462 1 2.000000E+00 -E_m_pz_d9_m3_e2 522 1 516 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m3_e1 521 523 482 1 2.000000E+00 -E_m_mz_d9_m3_e2 523 1 517 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m4_e1 463 524 2.983334E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m4_e2 483 525 2.983334E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m4_e1 524 1 526 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m4_e2 525 1 527 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m4_e1 527 1 528 1 Z0= 2.983334E+01 TD= 3.608721E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m4_e2 526 1 529 1 Z0= 2.983334E+01 TD= 3.608721E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m4_e1 527 1 2.983334E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m4_e2 526 1 2.983334E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m4_e1 528 530 463 1 2.000000E+00 -E_m_pz_d9_m4_e2 530 1 524 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m4_e1 529 531 483 1 2.000000E+00 -E_m_mz_d9_m4_e2 531 1 525 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_NGspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_NGspice.lib deleted file mode 100644 index d4c936a..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_NGspice.lib +++ /dev/null @@ -1,1540 +0,0 @@ -* Ngspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:spacewire name:spacewire conductor number 1 -* node: 3 cable number: 1 type:spacewire name:spacewire conductor number 2 -* node: 4 cable number: 1 type:spacewire name:spacewire conductor number 3 -* node: 5 cable number: 1 type:spacewire name:spacewire conductor number 4 -* node: 6 cable number: 1 type:spacewire name:spacewire conductor number 5 -* node: 7 cable number: 1 type:spacewire name:spacewire conductor number 6 -* node: 8 cable number: 1 type:spacewire name:spacewire conductor number 7 -* node: 9 cable number: 1 type:spacewire name:spacewire conductor number 8 -* node: 10 cable number: 1 type:spacewire name:spacewire conductor number 9 -* node: 11 cable number: 1 type:spacewire name:spacewire conductor number 10 -* node: 12 cable number: 1 type:spacewire name:spacewire conductor number 11 -* node: 13 cable number: 1 type:spacewire name:spacewire conductor number 12 -* node: 14 cable number: 1 type:spacewire name:spacewire conductor number 13 -* -* End 2 nodes: -* -* node: 15 cable number: 1 type:spacewire name:spacewire conductor number 1 -* node: 16 cable number: 1 type:spacewire name:spacewire conductor number 2 -* node: 17 cable number: 1 type:spacewire name:spacewire conductor number 3 -* node: 18 cable number: 1 type:spacewire name:spacewire conductor number 4 -* node: 19 cable number: 1 type:spacewire name:spacewire conductor number 5 -* node: 20 cable number: 1 type:spacewire name:spacewire conductor number 6 -* node: 21 cable number: 1 type:spacewire name:spacewire conductor number 7 -* node: 22 cable number: 1 type:spacewire name:spacewire conductor number 8 -* node: 23 cable number: 1 type:spacewire name:spacewire conductor number 9 -* node: 24 cable number: 1 type:spacewire name:spacewire conductor number 10 -* node: 25 cable number: 1 type:spacewire name:spacewire conductor number 11 -* node: 26 cable number: 1 type:spacewire name:spacewire conductor number 12 -* node: 27 cable number: 1 type:spacewire name:spacewire conductor number 13 -* -.subckt ZT_FD_Spacewire -+ 2 3 4 5 6 7 8 9 10 11 12 13 14 -+ 15 16 17 18 19 20 21 22 23 24 25 26 27 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 28 5.092958E-02 -Rdc_c2_e1 3 29 5.092958E-02 -Rdc_c3_e1 4 30 5.092958E-02 -Rdc_c4_e1 5 31 5.092958E-02 -Rdc_c5_e1 6 32 5.092958E-02 -Rdc_c6_e1 7 33 5.092958E-02 -Rdc_c7_e1 8 34 5.092958E-02 -Rdc_c8_e1 9 35 5.092958E-02 -Rdc_c9_e1 10 36 1.273240E-02 -Rdc_c10_e1 11 37 1.273240E-02 -Rdc_c11_e1 12 38 1.273240E-02 -Rdc_c12_e1 13 39 1.273240E-02 -Rdc_c13_e1 14 1 3.395291E-03 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 15 40 5.092958E-02 -Rdc_c2_e2 16 41 5.092958E-02 -Rdc_c3_e2 17 42 5.092958E-02 -Rdc_c4_e2 18 43 5.092958E-02 -Rdc_c5_e2 19 44 5.092958E-02 -Rdc_c6_e2 20 45 5.092958E-02 -Rdc_c7_e2 21 46 5.092958E-02 -Rdc_c8_e2 22 47 5.092958E-02 -Rdc_c9_e2 23 48 1.273240E-02 -Rdc_c10_e2 24 49 1.273240E-02 -Rdc_c11_e2 25 50 1.273240E-02 -Rdc_c12_e2 26 51 1.273240E-02 -Rdc_c13_e2 27 1 3.395291E-03 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 28 64 -Vmeas_domain_decomp_c2_e1 29 76 -Vmeas_domain_decomp_c3_e1 30 88 -Vmeas_domain_decomp_c4_e1 31 100 -Vmeas_domain_decomp_c5_e1 32 112 -Vmeas_domain_decomp_c6_e1 33 124 -Vmeas_domain_decomp_c7_e1 34 136 -Vmeas_domain_decomp_c8_e1 35 148 -Vmeas_domain_decomp_c9_e1 36 160 -Vmeas_domain_decomp_c10_e1 37 172 -Vmeas_domain_decomp_c11_e1 38 184 -Vmeas_domain_decomp_c12_e1 39 196 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 64 65 52 1 5.000000E-01 -E_domain_decomp_c1_dc2_e1 65 66 53 1 1.000000E+00 -E_domain_decomp_c1_dc3_e1 66 67 54 1 0.000000E+00 -E_domain_decomp_c1_dc4_e1 67 68 55 1 0.000000E+00 -E_domain_decomp_c1_dc5_e1 68 69 56 1 0.000000E+00 -E_domain_decomp_c1_dc6_e1 69 70 57 1 0.000000E+00 -E_domain_decomp_c1_dc7_e1 70 71 58 1 0.000000E+00 -E_domain_decomp_c1_dc8_e1 71 72 59 1 -0.000000E+00 -E_domain_decomp_c1_dc9_e1 72 73 60 1 1.000000E+00 -E_domain_decomp_c1_dc10_e1 73 74 61 1 0.000000E+00 -E_domain_decomp_c1_dc11_e1 74 75 62 1 0.000000E+00 -E_domain_decomp_c1_dc12_e1 75 1 63 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e1 76 77 52 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e1 77 78 53 1 1.000000E+00 -E_domain_decomp_c2_dc3_e1 78 79 54 1 0.000000E+00 -E_domain_decomp_c2_dc4_e1 79 80 55 1 0.000000E+00 -E_domain_decomp_c2_dc5_e1 80 81 56 1 0.000000E+00 -E_domain_decomp_c2_dc6_e1 81 82 57 1 0.000000E+00 -E_domain_decomp_c2_dc7_e1 82 83 58 1 0.000000E+00 -E_domain_decomp_c2_dc8_e1 83 84 59 1 -0.000000E+00 -E_domain_decomp_c2_dc9_e1 84 85 60 1 1.000000E+00 -E_domain_decomp_c2_dc10_e1 85 86 61 1 0.000000E+00 -E_domain_decomp_c2_dc11_e1 86 87 62 1 0.000000E+00 -E_domain_decomp_c2_dc12_e1 87 1 63 1 -0.000000E+00 -E_domain_decomp_c3_dc1_e1 88 89 52 1 0.000000E+00 -E_domain_decomp_c3_dc2_e1 89 90 53 1 0.000000E+00 -E_domain_decomp_c3_dc3_e1 90 91 54 1 5.000000E-01 -E_domain_decomp_c3_dc4_e1 91 92 55 1 1.000000E+00 -E_domain_decomp_c3_dc5_e1 92 93 56 1 0.000000E+00 -E_domain_decomp_c3_dc6_e1 93 94 57 1 0.000000E+00 -E_domain_decomp_c3_dc7_e1 94 95 58 1 0.000000E+00 -E_domain_decomp_c3_dc8_e1 95 96 59 1 0.000000E+00 -E_domain_decomp_c3_dc9_e1 96 97 60 1 -0.000000E+00 -E_domain_decomp_c3_dc10_e1 97 98 61 1 1.000000E+00 -E_domain_decomp_c3_dc11_e1 98 99 62 1 0.000000E+00 -E_domain_decomp_c3_dc12_e1 99 1 63 1 -0.000000E+00 -E_domain_decomp_c4_dc1_e1 100 101 52 1 0.000000E+00 -E_domain_decomp_c4_dc2_e1 101 102 53 1 0.000000E+00 -E_domain_decomp_c4_dc3_e1 102 103 54 1 -5.000000E-01 -E_domain_decomp_c4_dc4_e1 103 104 55 1 1.000000E+00 -E_domain_decomp_c4_dc5_e1 104 105 56 1 0.000000E+00 -E_domain_decomp_c4_dc6_e1 105 106 57 1 0.000000E+00 -E_domain_decomp_c4_dc7_e1 106 107 58 1 0.000000E+00 -E_domain_decomp_c4_dc8_e1 107 108 59 1 0.000000E+00 -E_domain_decomp_c4_dc9_e1 108 109 60 1 -0.000000E+00 -E_domain_decomp_c4_dc10_e1 109 110 61 1 1.000000E+00 -E_domain_decomp_c4_dc11_e1 110 111 62 1 0.000000E+00 -E_domain_decomp_c4_dc12_e1 111 1 63 1 -0.000000E+00 -E_domain_decomp_c5_dc1_e1 112 113 52 1 0.000000E+00 -E_domain_decomp_c5_dc2_e1 113 114 53 1 0.000000E+00 -E_domain_decomp_c5_dc3_e1 114 115 54 1 0.000000E+00 -E_domain_decomp_c5_dc4_e1 115 116 55 1 0.000000E+00 -E_domain_decomp_c5_dc5_e1 116 117 56 1 5.000000E-01 -E_domain_decomp_c5_dc6_e1 117 118 57 1 1.000000E+00 -E_domain_decomp_c5_dc7_e1 118 119 58 1 0.000000E+00 -E_domain_decomp_c5_dc8_e1 119 120 59 1 0.000000E+00 -E_domain_decomp_c5_dc9_e1 120 121 60 1 0.000000E+00 -E_domain_decomp_c5_dc10_e1 121 122 61 1 -0.000000E+00 -E_domain_decomp_c5_dc11_e1 122 123 62 1 1.000000E+00 -E_domain_decomp_c5_dc12_e1 123 1 63 1 -0.000000E+00 -E_domain_decomp_c6_dc1_e1 124 125 52 1 0.000000E+00 -E_domain_decomp_c6_dc2_e1 125 126 53 1 0.000000E+00 -E_domain_decomp_c6_dc3_e1 126 127 54 1 0.000000E+00 -E_domain_decomp_c6_dc4_e1 127 128 55 1 0.000000E+00 -E_domain_decomp_c6_dc5_e1 128 129 56 1 -5.000000E-01 -E_domain_decomp_c6_dc6_e1 129 130 57 1 1.000000E+00 -E_domain_decomp_c6_dc7_e1 130 131 58 1 0.000000E+00 -E_domain_decomp_c6_dc8_e1 131 132 59 1 0.000000E+00 -E_domain_decomp_c6_dc9_e1 132 133 60 1 0.000000E+00 -E_domain_decomp_c6_dc10_e1 133 134 61 1 -0.000000E+00 -E_domain_decomp_c6_dc11_e1 134 135 62 1 1.000000E+00 -E_domain_decomp_c6_dc12_e1 135 1 63 1 -0.000000E+00 -E_domain_decomp_c7_dc1_e1 136 137 52 1 0.000000E+00 -E_domain_decomp_c7_dc2_e1 137 138 53 1 0.000000E+00 -E_domain_decomp_c7_dc3_e1 138 139 54 1 0.000000E+00 -E_domain_decomp_c7_dc4_e1 139 140 55 1 0.000000E+00 -E_domain_decomp_c7_dc5_e1 140 141 56 1 0.000000E+00 -E_domain_decomp_c7_dc6_e1 141 142 57 1 0.000000E+00 -E_domain_decomp_c7_dc7_e1 142 143 58 1 5.000000E-01 -E_domain_decomp_c7_dc8_e1 143 144 59 1 1.000000E+00 -E_domain_decomp_c7_dc9_e1 144 145 60 1 0.000000E+00 -E_domain_decomp_c7_dc10_e1 145 146 61 1 0.000000E+00 -E_domain_decomp_c7_dc11_e1 146 147 62 1 -0.000000E+00 -E_domain_decomp_c7_dc12_e1 147 1 63 1 1.000000E+00 -E_domain_decomp_c8_dc1_e1 148 149 52 1 0.000000E+00 -E_domain_decomp_c8_dc2_e1 149 150 53 1 0.000000E+00 -E_domain_decomp_c8_dc3_e1 150 151 54 1 0.000000E+00 -E_domain_decomp_c8_dc4_e1 151 152 55 1 0.000000E+00 -E_domain_decomp_c8_dc5_e1 152 153 56 1 0.000000E+00 -E_domain_decomp_c8_dc6_e1 153 154 57 1 0.000000E+00 -E_domain_decomp_c8_dc7_e1 154 155 58 1 -5.000000E-01 -E_domain_decomp_c8_dc8_e1 155 156 59 1 1.000000E+00 -E_domain_decomp_c8_dc9_e1 156 157 60 1 0.000000E+00 -E_domain_decomp_c8_dc10_e1 157 158 61 1 0.000000E+00 -E_domain_decomp_c8_dc11_e1 158 159 62 1 -0.000000E+00 -E_domain_decomp_c8_dc12_e1 159 1 63 1 1.000000E+00 -E_domain_decomp_c9_dc1_e1 160 161 52 1 0.000000E+00 -E_domain_decomp_c9_dc2_e1 161 162 53 1 0.000000E+00 -E_domain_decomp_c9_dc3_e1 162 163 54 1 0.000000E+00 -E_domain_decomp_c9_dc4_e1 163 164 55 1 0.000000E+00 -E_domain_decomp_c9_dc5_e1 164 165 56 1 0.000000E+00 -E_domain_decomp_c9_dc6_e1 165 166 57 1 0.000000E+00 -E_domain_decomp_c9_dc7_e1 166 167 58 1 0.000000E+00 -E_domain_decomp_c9_dc8_e1 167 168 59 1 -0.000000E+00 -E_domain_decomp_c9_dc9_e1 168 169 60 1 1.000000E+00 -E_domain_decomp_c9_dc10_e1 169 170 61 1 0.000000E+00 -E_domain_decomp_c9_dc11_e1 170 171 62 1 0.000000E+00 -E_domain_decomp_c9_dc12_e1 171 1 63 1 -0.000000E+00 -E_domain_decomp_c10_dc1_e1 172 173 52 1 0.000000E+00 -E_domain_decomp_c10_dc2_e1 173 174 53 1 0.000000E+00 -E_domain_decomp_c10_dc3_e1 174 175 54 1 0.000000E+00 -E_domain_decomp_c10_dc4_e1 175 176 55 1 0.000000E+00 -E_domain_decomp_c10_dc5_e1 176 177 56 1 0.000000E+00 -E_domain_decomp_c10_dc6_e1 177 178 57 1 0.000000E+00 -E_domain_decomp_c10_dc7_e1 178 179 58 1 0.000000E+00 -E_domain_decomp_c10_dc8_e1 179 180 59 1 0.000000E+00 -E_domain_decomp_c10_dc9_e1 180 181 60 1 -0.000000E+00 -E_domain_decomp_c10_dc10_e1 181 182 61 1 1.000000E+00 -E_domain_decomp_c10_dc11_e1 182 183 62 1 0.000000E+00 -E_domain_decomp_c10_dc12_e1 183 1 63 1 -0.000000E+00 -E_domain_decomp_c11_dc1_e1 184 185 52 1 0.000000E+00 -E_domain_decomp_c11_dc2_e1 185 186 53 1 0.000000E+00 -E_domain_decomp_c11_dc3_e1 186 187 54 1 0.000000E+00 -E_domain_decomp_c11_dc4_e1 187 188 55 1 0.000000E+00 -E_domain_decomp_c11_dc5_e1 188 189 56 1 0.000000E+00 -E_domain_decomp_c11_dc6_e1 189 190 57 1 0.000000E+00 -E_domain_decomp_c11_dc7_e1 190 191 58 1 0.000000E+00 -E_domain_decomp_c11_dc8_e1 191 192 59 1 0.000000E+00 -E_domain_decomp_c11_dc9_e1 192 193 60 1 0.000000E+00 -E_domain_decomp_c11_dc10_e1 193 194 61 1 -0.000000E+00 -E_domain_decomp_c11_dc11_e1 194 195 62 1 1.000000E+00 -E_domain_decomp_c11_dc12_e1 195 1 63 1 -0.000000E+00 -E_domain_decomp_c12_dc1_e1 196 197 52 1 0.000000E+00 -E_domain_decomp_c12_dc2_e1 197 198 53 1 0.000000E+00 -E_domain_decomp_c12_dc3_e1 198 199 54 1 0.000000E+00 -E_domain_decomp_c12_dc4_e1 199 200 55 1 0.000000E+00 -E_domain_decomp_c12_dc5_e1 200 201 56 1 0.000000E+00 -E_domain_decomp_c12_dc6_e1 201 202 57 1 0.000000E+00 -E_domain_decomp_c12_dc7_e1 202 203 58 1 0.000000E+00 -E_domain_decomp_c12_dc8_e1 203 204 59 1 0.000000E+00 -E_domain_decomp_c12_dc9_e1 204 205 60 1 0.000000E+00 -E_domain_decomp_c12_dc10_e1 205 206 61 1 0.000000E+00 -E_domain_decomp_c12_dc11_e1 206 207 62 1 -0.000000E+00 -E_domain_decomp_c12_dc12_e1 207 1 63 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 52 Vmeas_domain_decomp_c1_e1 5.000000E-01 -F_domain_decomp_c2_dc1_e1 1 52 Vmeas_domain_decomp_c2_e1 -5.000000E-01 -F_domain_decomp_c3_dc1_e1 1 52 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc1_e1 1 52 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc1_e1 1 52 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc1_e1 1 52 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc1_e1 1 52 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc1_e1 1 52 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc1_e1 1 52 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc1_e1 1 52 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc1_e1 1 52 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc1_e1 1 52 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 53 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 53 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c3_dc2_e1 1 53 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc2_e1 1 53 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc2_e1 1 53 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc2_e1 1 53 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc2_e1 1 53 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc2_e1 1 53 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc2_e1 1 53 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc2_e1 1 53 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc2_e1 1 53 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc2_e1 1 53 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc3_e1 1 54 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc3_e1 1 54 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc3_e1 1 54 Vmeas_domain_decomp_c3_e1 5.000000E-01 -F_domain_decomp_c4_dc3_e1 1 54 Vmeas_domain_decomp_c4_e1 -5.000000E-01 -F_domain_decomp_c5_dc3_e1 1 54 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc3_e1 1 54 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc3_e1 1 54 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc3_e1 1 54 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc3_e1 1 54 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc3_e1 1 54 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc3_e1 1 54 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc3_e1 1 54 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc4_e1 1 55 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc4_e1 1 55 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc4_e1 1 55 Vmeas_domain_decomp_c3_e1 1.000000E+00 -F_domain_decomp_c4_dc4_e1 1 55 Vmeas_domain_decomp_c4_e1 1.000000E+00 -F_domain_decomp_c5_dc4_e1 1 55 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc4_e1 1 55 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc4_e1 1 55 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc4_e1 1 55 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc4_e1 1 55 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc4_e1 1 55 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc4_e1 1 55 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc4_e1 1 55 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc5_e1 1 56 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc5_e1 1 56 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc5_e1 1 56 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc5_e1 1 56 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc5_e1 1 56 Vmeas_domain_decomp_c5_e1 5.000000E-01 -F_domain_decomp_c6_dc5_e1 1 56 Vmeas_domain_decomp_c6_e1 -5.000000E-01 -F_domain_decomp_c7_dc5_e1 1 56 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc5_e1 1 56 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc5_e1 1 56 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc5_e1 1 56 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc5_e1 1 56 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc5_e1 1 56 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc6_e1 1 57 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc6_e1 1 57 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc6_e1 1 57 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc6_e1 1 57 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc6_e1 1 57 Vmeas_domain_decomp_c5_e1 1.000000E+00 -F_domain_decomp_c6_dc6_e1 1 57 Vmeas_domain_decomp_c6_e1 1.000000E+00 -F_domain_decomp_c7_dc6_e1 1 57 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc6_e1 1 57 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc6_e1 1 57 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc6_e1 1 57 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc6_e1 1 57 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc6_e1 1 57 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc7_e1 1 58 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc7_e1 1 58 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc7_e1 1 58 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc7_e1 1 58 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc7_e1 1 58 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc7_e1 1 58 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc7_e1 1 58 Vmeas_domain_decomp_c7_e1 5.000000E-01 -F_domain_decomp_c8_dc7_e1 1 58 Vmeas_domain_decomp_c8_e1 -5.000000E-01 -F_domain_decomp_c9_dc7_e1 1 58 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc7_e1 1 58 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc7_e1 1 58 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc7_e1 1 58 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc8_e1 1 59 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc8_e1 1 59 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc8_e1 1 59 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc8_e1 1 59 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc8_e1 1 59 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc8_e1 1 59 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc8_e1 1 59 Vmeas_domain_decomp_c7_e1 1.000000E+00 -F_domain_decomp_c8_dc8_e1 1 59 Vmeas_domain_decomp_c8_e1 1.000000E+00 -F_domain_decomp_c9_dc8_e1 1 59 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc8_e1 1 59 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc8_e1 1 59 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc8_e1 1 59 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc9_e1 1 60 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc9_e1 1 60 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c3_dc9_e1 1 60 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc9_e1 1 60 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc9_e1 1 60 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc9_e1 1 60 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc9_e1 1 60 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc9_e1 1 60 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc9_e1 1 60 Vmeas_domain_decomp_c9_e1 1.000000E+00 -F_domain_decomp_c10_dc9_e1 1 60 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc9_e1 1 60 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc9_e1 1 60 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc10_e1 1 61 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc10_e1 1 61 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc10_e1 1 61 Vmeas_domain_decomp_c3_e1 1.000000E+00 -F_domain_decomp_c4_dc10_e1 1 61 Vmeas_domain_decomp_c4_e1 1.000000E+00 -F_domain_decomp_c5_dc10_e1 1 61 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc10_e1 1 61 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc10_e1 1 61 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc10_e1 1 61 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc10_e1 1 61 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc10_e1 1 61 Vmeas_domain_decomp_c10_e1 1.000000E+00 -F_domain_decomp_c11_dc10_e1 1 61 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc10_e1 1 61 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc11_e1 1 62 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc11_e1 1 62 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc11_e1 1 62 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc11_e1 1 62 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc11_e1 1 62 Vmeas_domain_decomp_c5_e1 1.000000E+00 -F_domain_decomp_c6_dc11_e1 1 62 Vmeas_domain_decomp_c6_e1 1.000000E+00 -F_domain_decomp_c7_dc11_e1 1 62 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc11_e1 1 62 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc11_e1 1 62 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc11_e1 1 62 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc11_e1 1 62 Vmeas_domain_decomp_c11_e1 1.000000E+00 -F_domain_decomp_c12_dc11_e1 1 62 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc12_e1 1 63 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc12_e1 1 63 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc12_e1 1 63 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc12_e1 1 63 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc12_e1 1 63 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc12_e1 1 63 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc12_e1 1 63 Vmeas_domain_decomp_c7_e1 1.000000E+00 -F_domain_decomp_c8_dc12_e1 1 63 Vmeas_domain_decomp_c8_e1 1.000000E+00 -F_domain_decomp_c9_dc12_e1 1 63 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc12_e1 1 63 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc12_e1 1 63 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc12_e1 1 63 Vmeas_domain_decomp_c12_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 40 220 -Vmeas_domain_decomp_c2_e2 41 232 -Vmeas_domain_decomp_c3_e2 42 244 -Vmeas_domain_decomp_c4_e2 43 256 -Vmeas_domain_decomp_c5_e2 44 268 -Vmeas_domain_decomp_c6_e2 45 280 -Vmeas_domain_decomp_c7_e2 46 292 -Vmeas_domain_decomp_c8_e2 47 304 -Vmeas_domain_decomp_c9_e2 48 316 -Vmeas_domain_decomp_c10_e2 49 328 -Vmeas_domain_decomp_c11_e2 50 340 -Vmeas_domain_decomp_c12_e2 51 352 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 220 221 208 1 5.000000E-01 -E_domain_decomp_c1_dc2_e2 221 222 209 1 1.000000E+00 -E_domain_decomp_c1_dc3_e2 222 223 210 1 0.000000E+00 -E_domain_decomp_c1_dc4_e2 223 224 211 1 0.000000E+00 -E_domain_decomp_c1_dc5_e2 224 225 212 1 0.000000E+00 -E_domain_decomp_c1_dc6_e2 225 226 213 1 0.000000E+00 -E_domain_decomp_c1_dc7_e2 226 227 214 1 0.000000E+00 -E_domain_decomp_c1_dc8_e2 227 228 215 1 -0.000000E+00 -E_domain_decomp_c1_dc9_e2 228 229 216 1 1.000000E+00 -E_domain_decomp_c1_dc10_e2 229 230 217 1 0.000000E+00 -E_domain_decomp_c1_dc11_e2 230 231 218 1 0.000000E+00 -E_domain_decomp_c1_dc12_e2 231 1 219 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e2 232 233 208 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e2 233 234 209 1 1.000000E+00 -E_domain_decomp_c2_dc3_e2 234 235 210 1 0.000000E+00 -E_domain_decomp_c2_dc4_e2 235 236 211 1 0.000000E+00 -E_domain_decomp_c2_dc5_e2 236 237 212 1 0.000000E+00 -E_domain_decomp_c2_dc6_e2 237 238 213 1 0.000000E+00 -E_domain_decomp_c2_dc7_e2 238 239 214 1 0.000000E+00 -E_domain_decomp_c2_dc8_e2 239 240 215 1 -0.000000E+00 -E_domain_decomp_c2_dc9_e2 240 241 216 1 1.000000E+00 -E_domain_decomp_c2_dc10_e2 241 242 217 1 0.000000E+00 -E_domain_decomp_c2_dc11_e2 242 243 218 1 0.000000E+00 -E_domain_decomp_c2_dc12_e2 243 1 219 1 -0.000000E+00 -E_domain_decomp_c3_dc1_e2 244 245 208 1 0.000000E+00 -E_domain_decomp_c3_dc2_e2 245 246 209 1 0.000000E+00 -E_domain_decomp_c3_dc3_e2 246 247 210 1 5.000000E-01 -E_domain_decomp_c3_dc4_e2 247 248 211 1 1.000000E+00 -E_domain_decomp_c3_dc5_e2 248 249 212 1 0.000000E+00 -E_domain_decomp_c3_dc6_e2 249 250 213 1 0.000000E+00 -E_domain_decomp_c3_dc7_e2 250 251 214 1 0.000000E+00 -E_domain_decomp_c3_dc8_e2 251 252 215 1 0.000000E+00 -E_domain_decomp_c3_dc9_e2 252 253 216 1 -0.000000E+00 -E_domain_decomp_c3_dc10_e2 253 254 217 1 1.000000E+00 -E_domain_decomp_c3_dc11_e2 254 255 218 1 0.000000E+00 -E_domain_decomp_c3_dc12_e2 255 1 219 1 -0.000000E+00 -E_domain_decomp_c4_dc1_e2 256 257 208 1 0.000000E+00 -E_domain_decomp_c4_dc2_e2 257 258 209 1 0.000000E+00 -E_domain_decomp_c4_dc3_e2 258 259 210 1 -5.000000E-01 -E_domain_decomp_c4_dc4_e2 259 260 211 1 1.000000E+00 -E_domain_decomp_c4_dc5_e2 260 261 212 1 0.000000E+00 -E_domain_decomp_c4_dc6_e2 261 262 213 1 0.000000E+00 -E_domain_decomp_c4_dc7_e2 262 263 214 1 0.000000E+00 -E_domain_decomp_c4_dc8_e2 263 264 215 1 0.000000E+00 -E_domain_decomp_c4_dc9_e2 264 265 216 1 -0.000000E+00 -E_domain_decomp_c4_dc10_e2 265 266 217 1 1.000000E+00 -E_domain_decomp_c4_dc11_e2 266 267 218 1 0.000000E+00 -E_domain_decomp_c4_dc12_e2 267 1 219 1 -0.000000E+00 -E_domain_decomp_c5_dc1_e2 268 269 208 1 0.000000E+00 -E_domain_decomp_c5_dc2_e2 269 270 209 1 0.000000E+00 -E_domain_decomp_c5_dc3_e2 270 271 210 1 0.000000E+00 -E_domain_decomp_c5_dc4_e2 271 272 211 1 0.000000E+00 -E_domain_decomp_c5_dc5_e2 272 273 212 1 5.000000E-01 -E_domain_decomp_c5_dc6_e2 273 274 213 1 1.000000E+00 -E_domain_decomp_c5_dc7_e2 274 275 214 1 0.000000E+00 -E_domain_decomp_c5_dc8_e2 275 276 215 1 0.000000E+00 -E_domain_decomp_c5_dc9_e2 276 277 216 1 0.000000E+00 -E_domain_decomp_c5_dc10_e2 277 278 217 1 -0.000000E+00 -E_domain_decomp_c5_dc11_e2 278 279 218 1 1.000000E+00 -E_domain_decomp_c5_dc12_e2 279 1 219 1 -0.000000E+00 -E_domain_decomp_c6_dc1_e2 280 281 208 1 0.000000E+00 -E_domain_decomp_c6_dc2_e2 281 282 209 1 0.000000E+00 -E_domain_decomp_c6_dc3_e2 282 283 210 1 0.000000E+00 -E_domain_decomp_c6_dc4_e2 283 284 211 1 0.000000E+00 -E_domain_decomp_c6_dc5_e2 284 285 212 1 -5.000000E-01 -E_domain_decomp_c6_dc6_e2 285 286 213 1 1.000000E+00 -E_domain_decomp_c6_dc7_e2 286 287 214 1 0.000000E+00 -E_domain_decomp_c6_dc8_e2 287 288 215 1 0.000000E+00 -E_domain_decomp_c6_dc9_e2 288 289 216 1 0.000000E+00 -E_domain_decomp_c6_dc10_e2 289 290 217 1 -0.000000E+00 -E_domain_decomp_c6_dc11_e2 290 291 218 1 1.000000E+00 -E_domain_decomp_c6_dc12_e2 291 1 219 1 -0.000000E+00 -E_domain_decomp_c7_dc1_e2 292 293 208 1 0.000000E+00 -E_domain_decomp_c7_dc2_e2 293 294 209 1 0.000000E+00 -E_domain_decomp_c7_dc3_e2 294 295 210 1 0.000000E+00 -E_domain_decomp_c7_dc4_e2 295 296 211 1 0.000000E+00 -E_domain_decomp_c7_dc5_e2 296 297 212 1 0.000000E+00 -E_domain_decomp_c7_dc6_e2 297 298 213 1 0.000000E+00 -E_domain_decomp_c7_dc7_e2 298 299 214 1 5.000000E-01 -E_domain_decomp_c7_dc8_e2 299 300 215 1 1.000000E+00 -E_domain_decomp_c7_dc9_e2 300 301 216 1 0.000000E+00 -E_domain_decomp_c7_dc10_e2 301 302 217 1 0.000000E+00 -E_domain_decomp_c7_dc11_e2 302 303 218 1 -0.000000E+00 -E_domain_decomp_c7_dc12_e2 303 1 219 1 1.000000E+00 -E_domain_decomp_c8_dc1_e2 304 305 208 1 0.000000E+00 -E_domain_decomp_c8_dc2_e2 305 306 209 1 0.000000E+00 -E_domain_decomp_c8_dc3_e2 306 307 210 1 0.000000E+00 -E_domain_decomp_c8_dc4_e2 307 308 211 1 0.000000E+00 -E_domain_decomp_c8_dc5_e2 308 309 212 1 0.000000E+00 -E_domain_decomp_c8_dc6_e2 309 310 213 1 0.000000E+00 -E_domain_decomp_c8_dc7_e2 310 311 214 1 -5.000000E-01 -E_domain_decomp_c8_dc8_e2 311 312 215 1 1.000000E+00 -E_domain_decomp_c8_dc9_e2 312 313 216 1 0.000000E+00 -E_domain_decomp_c8_dc10_e2 313 314 217 1 0.000000E+00 -E_domain_decomp_c8_dc11_e2 314 315 218 1 -0.000000E+00 -E_domain_decomp_c8_dc12_e2 315 1 219 1 1.000000E+00 -E_domain_decomp_c9_dc1_e2 316 317 208 1 0.000000E+00 -E_domain_decomp_c9_dc2_e2 317 318 209 1 0.000000E+00 -E_domain_decomp_c9_dc3_e2 318 319 210 1 0.000000E+00 -E_domain_decomp_c9_dc4_e2 319 320 211 1 0.000000E+00 -E_domain_decomp_c9_dc5_e2 320 321 212 1 0.000000E+00 -E_domain_decomp_c9_dc6_e2 321 322 213 1 0.000000E+00 -E_domain_decomp_c9_dc7_e2 322 323 214 1 0.000000E+00 -E_domain_decomp_c9_dc8_e2 323 324 215 1 -0.000000E+00 -E_domain_decomp_c9_dc9_e2 324 325 216 1 1.000000E+00 -E_domain_decomp_c9_dc10_e2 325 326 217 1 0.000000E+00 -E_domain_decomp_c9_dc11_e2 326 327 218 1 0.000000E+00 -E_domain_decomp_c9_dc12_e2 327 1 219 1 -0.000000E+00 -E_domain_decomp_c10_dc1_e2 328 329 208 1 0.000000E+00 -E_domain_decomp_c10_dc2_e2 329 330 209 1 0.000000E+00 -E_domain_decomp_c10_dc3_e2 330 331 210 1 0.000000E+00 -E_domain_decomp_c10_dc4_e2 331 332 211 1 0.000000E+00 -E_domain_decomp_c10_dc5_e2 332 333 212 1 0.000000E+00 -E_domain_decomp_c10_dc6_e2 333 334 213 1 0.000000E+00 -E_domain_decomp_c10_dc7_e2 334 335 214 1 0.000000E+00 -E_domain_decomp_c10_dc8_e2 335 336 215 1 0.000000E+00 -E_domain_decomp_c10_dc9_e2 336 337 216 1 -0.000000E+00 -E_domain_decomp_c10_dc10_e2 337 338 217 1 1.000000E+00 -E_domain_decomp_c10_dc11_e2 338 339 218 1 0.000000E+00 -E_domain_decomp_c10_dc12_e2 339 1 219 1 -0.000000E+00 -E_domain_decomp_c11_dc1_e2 340 341 208 1 0.000000E+00 -E_domain_decomp_c11_dc2_e2 341 342 209 1 0.000000E+00 -E_domain_decomp_c11_dc3_e2 342 343 210 1 0.000000E+00 -E_domain_decomp_c11_dc4_e2 343 344 211 1 0.000000E+00 -E_domain_decomp_c11_dc5_e2 344 345 212 1 0.000000E+00 -E_domain_decomp_c11_dc6_e2 345 346 213 1 0.000000E+00 -E_domain_decomp_c11_dc7_e2 346 347 214 1 0.000000E+00 -E_domain_decomp_c11_dc8_e2 347 348 215 1 0.000000E+00 -E_domain_decomp_c11_dc9_e2 348 349 216 1 0.000000E+00 -E_domain_decomp_c11_dc10_e2 349 350 217 1 -0.000000E+00 -E_domain_decomp_c11_dc11_e2 350 351 218 1 1.000000E+00 -E_domain_decomp_c11_dc12_e2 351 1 219 1 -0.000000E+00 -E_domain_decomp_c12_dc1_e2 352 353 208 1 0.000000E+00 -E_domain_decomp_c12_dc2_e2 353 354 209 1 0.000000E+00 -E_domain_decomp_c12_dc3_e2 354 355 210 1 0.000000E+00 -E_domain_decomp_c12_dc4_e2 355 356 211 1 0.000000E+00 -E_domain_decomp_c12_dc5_e2 356 357 212 1 0.000000E+00 -E_domain_decomp_c12_dc6_e2 357 358 213 1 0.000000E+00 -E_domain_decomp_c12_dc7_e2 358 359 214 1 0.000000E+00 -E_domain_decomp_c12_dc8_e2 359 360 215 1 0.000000E+00 -E_domain_decomp_c12_dc9_e2 360 361 216 1 0.000000E+00 -E_domain_decomp_c12_dc10_e2 361 362 217 1 0.000000E+00 -E_domain_decomp_c12_dc11_e2 362 363 218 1 -0.000000E+00 -E_domain_decomp_c12_dc12_e2 363 1 219 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 208 Vmeas_domain_decomp_c1_e2 5.000000E-01 -F_domain_decomp_c2_dc1_e2 1 208 Vmeas_domain_decomp_c2_e2 -5.000000E-01 -F_domain_decomp_c3_dc1_e2 1 208 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc1_e2 1 208 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc1_e2 1 208 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc1_e2 1 208 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc1_e2 1 208 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc1_e2 1 208 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc1_e2 1 208 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc1_e2 1 208 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc1_e2 1 208 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc1_e2 1 208 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 209 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 209 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c3_dc2_e2 1 209 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc2_e2 1 209 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc2_e2 1 209 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc2_e2 1 209 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc2_e2 1 209 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc2_e2 1 209 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc2_e2 1 209 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc2_e2 1 209 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc2_e2 1 209 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc2_e2 1 209 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc3_e2 1 210 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc3_e2 1 210 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc3_e2 1 210 Vmeas_domain_decomp_c3_e2 5.000000E-01 -F_domain_decomp_c4_dc3_e2 1 210 Vmeas_domain_decomp_c4_e2 -5.000000E-01 -F_domain_decomp_c5_dc3_e2 1 210 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc3_e2 1 210 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc3_e2 1 210 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc3_e2 1 210 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc3_e2 1 210 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc3_e2 1 210 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc3_e2 1 210 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc3_e2 1 210 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc4_e2 1 211 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc4_e2 1 211 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc4_e2 1 211 Vmeas_domain_decomp_c3_e2 1.000000E+00 -F_domain_decomp_c4_dc4_e2 1 211 Vmeas_domain_decomp_c4_e2 1.000000E+00 -F_domain_decomp_c5_dc4_e2 1 211 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc4_e2 1 211 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc4_e2 1 211 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc4_e2 1 211 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc4_e2 1 211 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc4_e2 1 211 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc4_e2 1 211 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc4_e2 1 211 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc5_e2 1 212 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc5_e2 1 212 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc5_e2 1 212 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc5_e2 1 212 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc5_e2 1 212 Vmeas_domain_decomp_c5_e2 5.000000E-01 -F_domain_decomp_c6_dc5_e2 1 212 Vmeas_domain_decomp_c6_e2 -5.000000E-01 -F_domain_decomp_c7_dc5_e2 1 212 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc5_e2 1 212 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc5_e2 1 212 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc5_e2 1 212 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc5_e2 1 212 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc5_e2 1 212 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc6_e2 1 213 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc6_e2 1 213 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc6_e2 1 213 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc6_e2 1 213 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc6_e2 1 213 Vmeas_domain_decomp_c5_e2 1.000000E+00 -F_domain_decomp_c6_dc6_e2 1 213 Vmeas_domain_decomp_c6_e2 1.000000E+00 -F_domain_decomp_c7_dc6_e2 1 213 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc6_e2 1 213 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc6_e2 1 213 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc6_e2 1 213 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc6_e2 1 213 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc6_e2 1 213 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc7_e2 1 214 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc7_e2 1 214 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc7_e2 1 214 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc7_e2 1 214 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc7_e2 1 214 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc7_e2 1 214 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc7_e2 1 214 Vmeas_domain_decomp_c7_e2 5.000000E-01 -F_domain_decomp_c8_dc7_e2 1 214 Vmeas_domain_decomp_c8_e2 -5.000000E-01 -F_domain_decomp_c9_dc7_e2 1 214 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc7_e2 1 214 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc7_e2 1 214 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc7_e2 1 214 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc8_e2 1 215 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc8_e2 1 215 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc8_e2 1 215 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc8_e2 1 215 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc8_e2 1 215 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc8_e2 1 215 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc8_e2 1 215 Vmeas_domain_decomp_c7_e2 1.000000E+00 -F_domain_decomp_c8_dc8_e2 1 215 Vmeas_domain_decomp_c8_e2 1.000000E+00 -F_domain_decomp_c9_dc8_e2 1 215 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc8_e2 1 215 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc8_e2 1 215 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc8_e2 1 215 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc9_e2 1 216 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc9_e2 1 216 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c3_dc9_e2 1 216 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc9_e2 1 216 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc9_e2 1 216 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc9_e2 1 216 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc9_e2 1 216 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc9_e2 1 216 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc9_e2 1 216 Vmeas_domain_decomp_c9_e2 1.000000E+00 -F_domain_decomp_c10_dc9_e2 1 216 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc9_e2 1 216 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc9_e2 1 216 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc10_e2 1 217 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc10_e2 1 217 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc10_e2 1 217 Vmeas_domain_decomp_c3_e2 1.000000E+00 -F_domain_decomp_c4_dc10_e2 1 217 Vmeas_domain_decomp_c4_e2 1.000000E+00 -F_domain_decomp_c5_dc10_e2 1 217 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc10_e2 1 217 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc10_e2 1 217 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc10_e2 1 217 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc10_e2 1 217 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc10_e2 1 217 Vmeas_domain_decomp_c10_e2 1.000000E+00 -F_domain_decomp_c11_dc10_e2 1 217 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc10_e2 1 217 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc11_e2 1 218 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc11_e2 1 218 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc11_e2 1 218 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc11_e2 1 218 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc11_e2 1 218 Vmeas_domain_decomp_c5_e2 1.000000E+00 -F_domain_decomp_c6_dc11_e2 1 218 Vmeas_domain_decomp_c6_e2 1.000000E+00 -F_domain_decomp_c7_dc11_e2 1 218 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc11_e2 1 218 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc11_e2 1 218 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc11_e2 1 218 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc11_e2 1 218 Vmeas_domain_decomp_c11_e2 1.000000E+00 -F_domain_decomp_c12_dc11_e2 1 218 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc12_e2 1 219 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc12_e2 1 219 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc12_e2 1 219 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc12_e2 1 219 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc12_e2 1 219 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc12_e2 1 219 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc12_e2 1 219 Vmeas_domain_decomp_c7_e2 1.000000E+00 -F_domain_decomp_c8_dc12_e2 1 219 Vmeas_domain_decomp_c8_e2 1.000000E+00 -F_domain_decomp_c9_dc12_e2 1 219 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc12_e2 1 219 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc12_e2 1 219 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc12_e2 1 219 Vmeas_domain_decomp_c12_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 52 365 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 365 1 364 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 364 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 208 367 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 367 1 366 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 366 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 364 368 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 366 369 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 368 1 370 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 369 1 371 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 371 1 372 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 370 1 373 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 371 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 370 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 372 374 364 1 2.000000E+00 -E_m_pz_d1_m1_e2 374 1 368 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 373 375 366 1 2.000000E+00 -E_m_mz_d1_m1_e2 375 1 369 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 53 377 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 377 1 376 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 376 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 209 379 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 379 1 378 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 378 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 376 380 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 378 381 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 380 1 382 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 381 1 383 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 383 1 384 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 382 1 385 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 383 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 382 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 384 386 376 1 2.000000E+00 -E_m_pz_d2_m1_e2 386 1 380 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 385 387 378 1 2.000000E+00 -E_m_mz_d2_m1_e2 387 1 381 1 -1.000000E+00 -* -* DOMAIN 3 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d3_c1_e1 54 389 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d3_c1_m1_e1 389 1 388 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d3_c1_m1_e1 1 388 Vmeas_mode_decomp_d3_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d3_c1_e2 210 391 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d3_c1_m1_e2 391 1 390 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d3_c1_m1_e2 1 390 Vmeas_mode_decomp_d3_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d3_m1_e1 388 392 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d3_m1_e2 390 393 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d3_m1_e1 392 1 394 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d3_m1_e2 393 1 395 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d3_m1_e1 395 1 396 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d3_m1_e2 394 1 397 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d3_m1_e1 395 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d3_m1_e2 394 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d3_m1_e1 396 398 388 1 2.000000E+00 -E_m_pz_d3_m1_e2 398 1 392 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d3_m1_e1 397 399 390 1 2.000000E+00 -E_m_mz_d3_m1_e2 399 1 393 1 -1.000000E+00 -* -* DOMAIN 4 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d4_c1_e1 55 401 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d4_c1_m1_e1 401 1 400 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d4_c1_m1_e1 1 400 Vmeas_mode_decomp_d4_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d4_c1_e2 211 403 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d4_c1_m1_e2 403 1 402 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d4_c1_m1_e2 1 402 Vmeas_mode_decomp_d4_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d4_m1_e1 400 404 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d4_m1_e2 402 405 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d4_m1_e1 404 1 406 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d4_m1_e2 405 1 407 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d4_m1_e1 407 1 408 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d4_m1_e2 406 1 409 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d4_m1_e1 407 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d4_m1_e2 406 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d4_m1_e1 408 410 400 1 2.000000E+00 -E_m_pz_d4_m1_e2 410 1 404 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d4_m1_e1 409 411 402 1 2.000000E+00 -E_m_mz_d4_m1_e2 411 1 405 1 -1.000000E+00 -* -* DOMAIN 5 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d5_c1_e1 56 413 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d5_c1_m1_e1 413 1 412 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d5_c1_m1_e1 1 412 Vmeas_mode_decomp_d5_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d5_c1_e2 212 415 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d5_c1_m1_e2 415 1 414 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d5_c1_m1_e2 1 414 Vmeas_mode_decomp_d5_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d5_m1_e1 412 416 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d5_m1_e2 414 417 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d5_m1_e1 416 1 418 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d5_m1_e2 417 1 419 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d5_m1_e1 419 1 420 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d5_m1_e2 418 1 421 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d5_m1_e1 419 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d5_m1_e2 418 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d5_m1_e1 420 422 412 1 2.000000E+00 -E_m_pz_d5_m1_e2 422 1 416 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d5_m1_e1 421 423 414 1 2.000000E+00 -E_m_mz_d5_m1_e2 423 1 417 1 -1.000000E+00 -* -* DOMAIN 6 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d6_c1_e1 57 425 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d6_c1_m1_e1 425 1 424 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d6_c1_m1_e1 1 424 Vmeas_mode_decomp_d6_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d6_c1_e2 213 427 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d6_c1_m1_e2 427 1 426 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d6_c1_m1_e2 1 426 Vmeas_mode_decomp_d6_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d6_m1_e1 424 428 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d6_m1_e2 426 429 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d6_m1_e1 428 1 430 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d6_m1_e2 429 1 431 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d6_m1_e1 431 1 432 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d6_m1_e2 430 1 433 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d6_m1_e1 431 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d6_m1_e2 430 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d6_m1_e1 432 434 424 1 2.000000E+00 -E_m_pz_d6_m1_e2 434 1 428 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d6_m1_e1 433 435 426 1 2.000000E+00 -E_m_mz_d6_m1_e2 435 1 429 1 -1.000000E+00 -* -* DOMAIN 7 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d7_c1_e1 58 437 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d7_c1_m1_e1 437 1 436 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d7_c1_m1_e1 1 436 Vmeas_mode_decomp_d7_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d7_c1_e2 214 439 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d7_c1_m1_e2 439 1 438 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d7_c1_m1_e2 1 438 Vmeas_mode_decomp_d7_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d7_m1_e1 436 440 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d7_m1_e2 438 441 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d7_m1_e1 440 1 442 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d7_m1_e2 441 1 443 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d7_m1_e1 443 1 444 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d7_m1_e2 442 1 445 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d7_m1_e1 443 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d7_m1_e2 442 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d7_m1_e1 444 446 436 1 2.000000E+00 -E_m_pz_d7_m1_e2 446 1 440 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d7_m1_e1 445 447 438 1 2.000000E+00 -E_m_mz_d7_m1_e2 447 1 441 1 -1.000000E+00 -* -* DOMAIN 8 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d8_c1_e1 59 449 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d8_c1_m1_e1 449 1 448 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d8_c1_m1_e1 1 448 Vmeas_mode_decomp_d8_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d8_c1_e2 215 451 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d8_c1_m1_e2 451 1 450 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d8_c1_m1_e2 1 450 Vmeas_mode_decomp_d8_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d8_m1_e1 448 452 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d8_m1_e2 450 453 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d8_m1_e1 452 1 454 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d8_m1_e2 453 1 455 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d8_m1_e1 455 1 456 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d8_m1_e2 454 1 457 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d8_m1_e1 455 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d8_m1_e2 454 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d8_m1_e1 456 458 448 1 2.000000E+00 -E_m_pz_d8_m1_e2 458 1 452 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d8_m1_e1 457 459 450 1 2.000000E+00 -E_m_mz_d8_m1_e2 459 1 453 1 -1.000000E+00 -* -* DOMAIN 9 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d9_c1_e1 60 464 -Vmeas_mode_decomp_d9_c2_e1 61 468 -Vmeas_mode_decomp_d9_c3_e1 62 472 -Vmeas_mode_decomp_d9_c4_e1 63 476 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d9_c1_m1_e1 464 465 460 1 4.99997010E-01 -E_mode_decomp_d9_c1_m2_e1 465 466 461 1 6.60299603E-01 -E_mode_decomp_d9_c1_m3_e1 466 467 462 1 -2.52110920E-01 -E_mode_decomp_d9_c1_m4_e1 467 1 463 1 5.00566867E-01 -E_mode_decomp_d9_c2_m1_e1 468 469 460 1 5.00000814E-01 -E_mode_decomp_d9_c2_m2_e1 469 470 461 1 2.52638434E-01 -E_mode_decomp_d9_c2_m3_e1 470 471 462 1 6.60216363E-01 -E_mode_decomp_d9_c2_m4_e1 471 1 463 1 -5.00372583E-01 -E_mode_decomp_d9_c3_m1_e1 472 473 460 1 5.00001652E-01 -E_mode_decomp_d9_c3_m2_e1 473 474 461 1 -6.60745021E-01 -E_mode_decomp_d9_c3_m3_e1 474 475 462 1 2.52713880E-01 -E_mode_decomp_d9_c3_m4_e1 475 1 463 1 4.99437438E-01 -E_mode_decomp_d9_c4_m1_e1 476 477 460 1 5.00000524E-01 -E_mode_decomp_d9_c4_m2_e1 477 478 461 1 -2.52179072E-01 -E_mode_decomp_d9_c4_m3_e1 478 479 462 1 -6.60825366E-01 -E_mode_decomp_d9_c4_m4_e1 479 1 463 1 -4.99622234E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d9_c1_m1_e1 1 460 Vmeas_mode_decomp_d9_c1_e1 4.99997010E-01 -F_mode_decomp_d9_c2_m1_e1 1 460 Vmeas_mode_decomp_d9_c2_e1 5.00000814E-01 -F_mode_decomp_d9_c3_m1_e1 1 460 Vmeas_mode_decomp_d9_c3_e1 5.00001652E-01 -F_mode_decomp_d9_c4_m1_e1 1 460 Vmeas_mode_decomp_d9_c4_e1 5.00000524E-01 -F_mode_decomp_d9_c1_m2_e1 1 461 Vmeas_mode_decomp_d9_c1_e1 6.60299603E-01 -F_mode_decomp_d9_c2_m2_e1 1 461 Vmeas_mode_decomp_d9_c2_e1 2.52638434E-01 -F_mode_decomp_d9_c3_m2_e1 1 461 Vmeas_mode_decomp_d9_c3_e1 -6.60745021E-01 -F_mode_decomp_d9_c4_m2_e1 1 461 Vmeas_mode_decomp_d9_c4_e1 -2.52179072E-01 -F_mode_decomp_d9_c1_m3_e1 1 462 Vmeas_mode_decomp_d9_c1_e1 -2.52110920E-01 -F_mode_decomp_d9_c2_m3_e1 1 462 Vmeas_mode_decomp_d9_c2_e1 6.60216363E-01 -F_mode_decomp_d9_c3_m3_e1 1 462 Vmeas_mode_decomp_d9_c3_e1 2.52713880E-01 -F_mode_decomp_d9_c4_m3_e1 1 462 Vmeas_mode_decomp_d9_c4_e1 -6.60825366E-01 -F_mode_decomp_d9_c1_m4_e1 1 463 Vmeas_mode_decomp_d9_c1_e1 5.00566867E-01 -F_mode_decomp_d9_c2_m4_e1 1 463 Vmeas_mode_decomp_d9_c2_e1 -5.00372583E-01 -F_mode_decomp_d9_c3_m4_e1 1 463 Vmeas_mode_decomp_d9_c3_e1 4.99437438E-01 -F_mode_decomp_d9_c4_m4_e1 1 463 Vmeas_mode_decomp_d9_c4_e1 -4.99622234E-01 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d9_c1_e2 216 484 -Vmeas_mode_decomp_d9_c2_e2 217 488 -Vmeas_mode_decomp_d9_c3_e2 218 492 -Vmeas_mode_decomp_d9_c4_e2 219 496 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d9_c1_m1_e2 484 485 480 1 4.99997010E-01 -E_mode_decomp_d9_c1_m2_e2 485 486 481 1 6.60299603E-01 -E_mode_decomp_d9_c1_m3_e2 486 487 482 1 -2.52110920E-01 -E_mode_decomp_d9_c1_m4_e2 487 1 483 1 5.00566867E-01 -E_mode_decomp_d9_c2_m1_e2 488 489 480 1 5.00000814E-01 -E_mode_decomp_d9_c2_m2_e2 489 490 481 1 2.52638434E-01 -E_mode_decomp_d9_c2_m3_e2 490 491 482 1 6.60216363E-01 -E_mode_decomp_d9_c2_m4_e2 491 1 483 1 -5.00372583E-01 -E_mode_decomp_d9_c3_m1_e2 492 493 480 1 5.00001652E-01 -E_mode_decomp_d9_c3_m2_e2 493 494 481 1 -6.60745021E-01 -E_mode_decomp_d9_c3_m3_e2 494 495 482 1 2.52713880E-01 -E_mode_decomp_d9_c3_m4_e2 495 1 483 1 4.99437438E-01 -E_mode_decomp_d9_c4_m1_e2 496 497 480 1 5.00000524E-01 -E_mode_decomp_d9_c4_m2_e2 497 498 481 1 -2.52179072E-01 -E_mode_decomp_d9_c4_m3_e2 498 499 482 1 -6.60825366E-01 -E_mode_decomp_d9_c4_m4_e2 499 1 483 1 -4.99622234E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d9_c1_m1_e2 1 480 Vmeas_mode_decomp_d9_c1_e2 4.99997010E-01 -F_mode_decomp_d9_c2_m1_e2 1 480 Vmeas_mode_decomp_d9_c2_e2 5.00000814E-01 -F_mode_decomp_d9_c3_m1_e2 1 480 Vmeas_mode_decomp_d9_c3_e2 5.00001652E-01 -F_mode_decomp_d9_c4_m1_e2 1 480 Vmeas_mode_decomp_d9_c4_e2 5.00000524E-01 -F_mode_decomp_d9_c1_m2_e2 1 481 Vmeas_mode_decomp_d9_c1_e2 6.60299603E-01 -F_mode_decomp_d9_c2_m2_e2 1 481 Vmeas_mode_decomp_d9_c2_e2 2.52638434E-01 -F_mode_decomp_d9_c3_m2_e2 1 481 Vmeas_mode_decomp_d9_c3_e2 -6.60745021E-01 -F_mode_decomp_d9_c4_m2_e2 1 481 Vmeas_mode_decomp_d9_c4_e2 -2.52179072E-01 -F_mode_decomp_d9_c1_m3_e2 1 482 Vmeas_mode_decomp_d9_c1_e2 -2.52110920E-01 -F_mode_decomp_d9_c2_m3_e2 1 482 Vmeas_mode_decomp_d9_c2_e2 6.60216363E-01 -F_mode_decomp_d9_c3_m3_e2 1 482 Vmeas_mode_decomp_d9_c3_e2 2.52713880E-01 -F_mode_decomp_d9_c4_m3_e2 1 482 Vmeas_mode_decomp_d9_c4_e2 -6.60825366E-01 -F_mode_decomp_d9_c1_m4_e2 1 483 Vmeas_mode_decomp_d9_c1_e2 5.00566867E-01 -F_mode_decomp_d9_c2_m4_e2 1 483 Vmeas_mode_decomp_d9_c2_e2 -5.00372583E-01 -F_mode_decomp_d9_c3_m4_e2 1 483 Vmeas_mode_decomp_d9_c3_e2 4.99437438E-01 -F_mode_decomp_d9_c4_m4_e2 1 483 Vmeas_mode_decomp_d9_c4_e2 -4.99622234E-01 -* -* Modal impedance: end1 -* -RZCm_d9_m1_e1 460 500 9.322448E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m1_e2 480 501 9.322448E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m1_e1 500 1 502 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m1_e2 501 1 503 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m1_e1 503 1 504 1 Z0= 9.322448E+01 TD= 3.471226E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m1_e2 502 1 505 1 Z0= 9.322448E+01 TD= 3.471226E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m1_e1 503 1 9.322448E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m1_e2 502 1 9.322448E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m1_e1 504 506 460 1 2.000000E+00 -E_m_pz_d9_m1_e2 506 1 500 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m1_e1 505 507 480 1 2.000000E+00 -E_m_mz_d9_m1_e2 507 1 501 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m2_e1 461 508 4.294265E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m2_e2 481 509 4.294265E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m2_e1 508 1 510 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m2_e2 509 1 511 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m2_e1 511 1 512 1 Z0= 4.294265E+01 TD= 3.563291E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m2_e2 510 1 513 1 Z0= 4.294265E+01 TD= 3.563291E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m2_e1 511 1 4.294265E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m2_e2 510 1 4.294265E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m2_e1 512 514 461 1 2.000000E+00 -E_m_pz_d9_m2_e2 514 1 508 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m2_e1 513 515 481 1 2.000000E+00 -E_m_mz_d9_m2_e2 515 1 509 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m3_e1 462 516 4.294177E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m3_e2 482 517 4.294177E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m3_e1 516 1 518 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m3_e2 517 1 519 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m3_e1 519 1 520 1 Z0= 4.294177E+01 TD= 3.563298E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m3_e2 518 1 521 1 Z0= 4.294177E+01 TD= 3.563298E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m3_e1 519 1 4.294177E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m3_e2 518 1 4.294177E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m3_e1 520 522 462 1 2.000000E+00 -E_m_pz_d9_m3_e2 522 1 516 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m3_e1 521 523 482 1 2.000000E+00 -E_m_mz_d9_m3_e2 523 1 517 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m4_e1 463 524 2.983334E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m4_e2 483 525 2.983334E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m4_e1 524 1 526 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m4_e2 525 1 527 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m4_e1 527 1 528 1 Z0= 2.983334E+01 TD= 3.608721E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m4_e2 526 1 529 1 Z0= 2.983334E+01 TD= 3.608721E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m4_e1 527 1 2.983334E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m4_e2 526 1 2.983334E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m4_e1 528 530 463 1 2.000000E+00 -E_m_pz_d9_m4_e2 530 1 524 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m4_e1 529 531 483 1 2.000000E+00 -E_m_mz_d9_m4_e2 531 1 525 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_Pspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_Pspice.lib deleted file mode 100644 index 5b093f5..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Spacewire_Pspice.lib +++ /dev/null @@ -1,1540 +0,0 @@ -* Pspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:spacewire name:spacewire conductor number 1 -* node: 3 cable number: 1 type:spacewire name:spacewire conductor number 2 -* node: 4 cable number: 1 type:spacewire name:spacewire conductor number 3 -* node: 5 cable number: 1 type:spacewire name:spacewire conductor number 4 -* node: 6 cable number: 1 type:spacewire name:spacewire conductor number 5 -* node: 7 cable number: 1 type:spacewire name:spacewire conductor number 6 -* node: 8 cable number: 1 type:spacewire name:spacewire conductor number 7 -* node: 9 cable number: 1 type:spacewire name:spacewire conductor number 8 -* node: 10 cable number: 1 type:spacewire name:spacewire conductor number 9 -* node: 11 cable number: 1 type:spacewire name:spacewire conductor number 10 -* node: 12 cable number: 1 type:spacewire name:spacewire conductor number 11 -* node: 13 cable number: 1 type:spacewire name:spacewire conductor number 12 -* node: 14 cable number: 1 type:spacewire name:spacewire conductor number 13 -* -* End 2 nodes: -* -* node: 15 cable number: 1 type:spacewire name:spacewire conductor number 1 -* node: 16 cable number: 1 type:spacewire name:spacewire conductor number 2 -* node: 17 cable number: 1 type:spacewire name:spacewire conductor number 3 -* node: 18 cable number: 1 type:spacewire name:spacewire conductor number 4 -* node: 19 cable number: 1 type:spacewire name:spacewire conductor number 5 -* node: 20 cable number: 1 type:spacewire name:spacewire conductor number 6 -* node: 21 cable number: 1 type:spacewire name:spacewire conductor number 7 -* node: 22 cable number: 1 type:spacewire name:spacewire conductor number 8 -* node: 23 cable number: 1 type:spacewire name:spacewire conductor number 9 -* node: 24 cable number: 1 type:spacewire name:spacewire conductor number 10 -* node: 25 cable number: 1 type:spacewire name:spacewire conductor number 11 -* node: 26 cable number: 1 type:spacewire name:spacewire conductor number 12 -* node: 27 cable number: 1 type:spacewire name:spacewire conductor number 13 -* -.subckt ZT_FD_Spacewire -+ 2 3 4 5 6 7 8 9 10 11 12 13 14 -+ 15 16 17 18 19 20 21 22 23 24 25 26 27 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 28 5.092958E-02 -Rdc_c2_e1 3 29 5.092958E-02 -Rdc_c3_e1 4 30 5.092958E-02 -Rdc_c4_e1 5 31 5.092958E-02 -Rdc_c5_e1 6 32 5.092958E-02 -Rdc_c6_e1 7 33 5.092958E-02 -Rdc_c7_e1 8 34 5.092958E-02 -Rdc_c8_e1 9 35 5.092958E-02 -Rdc_c9_e1 10 36 1.273240E-02 -Rdc_c10_e1 11 37 1.273240E-02 -Rdc_c11_e1 12 38 1.273240E-02 -Rdc_c12_e1 13 39 1.273240E-02 -Rdc_c13_e1 14 1 3.395291E-03 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 15 40 5.092958E-02 -Rdc_c2_e2 16 41 5.092958E-02 -Rdc_c3_e2 17 42 5.092958E-02 -Rdc_c4_e2 18 43 5.092958E-02 -Rdc_c5_e2 19 44 5.092958E-02 -Rdc_c6_e2 20 45 5.092958E-02 -Rdc_c7_e2 21 46 5.092958E-02 -Rdc_c8_e2 22 47 5.092958E-02 -Rdc_c9_e2 23 48 1.273240E-02 -Rdc_c10_e2 24 49 1.273240E-02 -Rdc_c11_e2 25 50 1.273240E-02 -Rdc_c12_e2 26 51 1.273240E-02 -Rdc_c13_e2 27 1 3.395291E-03 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 28 64 -Vmeas_domain_decomp_c2_e1 29 76 -Vmeas_domain_decomp_c3_e1 30 88 -Vmeas_domain_decomp_c4_e1 31 100 -Vmeas_domain_decomp_c5_e1 32 112 -Vmeas_domain_decomp_c6_e1 33 124 -Vmeas_domain_decomp_c7_e1 34 136 -Vmeas_domain_decomp_c8_e1 35 148 -Vmeas_domain_decomp_c9_e1 36 160 -Vmeas_domain_decomp_c10_e1 37 172 -Vmeas_domain_decomp_c11_e1 38 184 -Vmeas_domain_decomp_c12_e1 39 196 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 64 65 52 1 5.000000E-01 -E_domain_decomp_c1_dc2_e1 65 66 53 1 1.000000E+00 -E_domain_decomp_c1_dc3_e1 66 67 54 1 0.000000E+00 -E_domain_decomp_c1_dc4_e1 67 68 55 1 0.000000E+00 -E_domain_decomp_c1_dc5_e1 68 69 56 1 0.000000E+00 -E_domain_decomp_c1_dc6_e1 69 70 57 1 0.000000E+00 -E_domain_decomp_c1_dc7_e1 70 71 58 1 0.000000E+00 -E_domain_decomp_c1_dc8_e1 71 72 59 1 -0.000000E+00 -E_domain_decomp_c1_dc9_e1 72 73 60 1 1.000000E+00 -E_domain_decomp_c1_dc10_e1 73 74 61 1 0.000000E+00 -E_domain_decomp_c1_dc11_e1 74 75 62 1 0.000000E+00 -E_domain_decomp_c1_dc12_e1 75 1 63 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e1 76 77 52 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e1 77 78 53 1 1.000000E+00 -E_domain_decomp_c2_dc3_e1 78 79 54 1 0.000000E+00 -E_domain_decomp_c2_dc4_e1 79 80 55 1 0.000000E+00 -E_domain_decomp_c2_dc5_e1 80 81 56 1 0.000000E+00 -E_domain_decomp_c2_dc6_e1 81 82 57 1 0.000000E+00 -E_domain_decomp_c2_dc7_e1 82 83 58 1 0.000000E+00 -E_domain_decomp_c2_dc8_e1 83 84 59 1 -0.000000E+00 -E_domain_decomp_c2_dc9_e1 84 85 60 1 1.000000E+00 -E_domain_decomp_c2_dc10_e1 85 86 61 1 0.000000E+00 -E_domain_decomp_c2_dc11_e1 86 87 62 1 0.000000E+00 -E_domain_decomp_c2_dc12_e1 87 1 63 1 -0.000000E+00 -E_domain_decomp_c3_dc1_e1 88 89 52 1 0.000000E+00 -E_domain_decomp_c3_dc2_e1 89 90 53 1 0.000000E+00 -E_domain_decomp_c3_dc3_e1 90 91 54 1 5.000000E-01 -E_domain_decomp_c3_dc4_e1 91 92 55 1 1.000000E+00 -E_domain_decomp_c3_dc5_e1 92 93 56 1 0.000000E+00 -E_domain_decomp_c3_dc6_e1 93 94 57 1 0.000000E+00 -E_domain_decomp_c3_dc7_e1 94 95 58 1 0.000000E+00 -E_domain_decomp_c3_dc8_e1 95 96 59 1 0.000000E+00 -E_domain_decomp_c3_dc9_e1 96 97 60 1 -0.000000E+00 -E_domain_decomp_c3_dc10_e1 97 98 61 1 1.000000E+00 -E_domain_decomp_c3_dc11_e1 98 99 62 1 0.000000E+00 -E_domain_decomp_c3_dc12_e1 99 1 63 1 -0.000000E+00 -E_domain_decomp_c4_dc1_e1 100 101 52 1 0.000000E+00 -E_domain_decomp_c4_dc2_e1 101 102 53 1 0.000000E+00 -E_domain_decomp_c4_dc3_e1 102 103 54 1 -5.000000E-01 -E_domain_decomp_c4_dc4_e1 103 104 55 1 1.000000E+00 -E_domain_decomp_c4_dc5_e1 104 105 56 1 0.000000E+00 -E_domain_decomp_c4_dc6_e1 105 106 57 1 0.000000E+00 -E_domain_decomp_c4_dc7_e1 106 107 58 1 0.000000E+00 -E_domain_decomp_c4_dc8_e1 107 108 59 1 0.000000E+00 -E_domain_decomp_c4_dc9_e1 108 109 60 1 -0.000000E+00 -E_domain_decomp_c4_dc10_e1 109 110 61 1 1.000000E+00 -E_domain_decomp_c4_dc11_e1 110 111 62 1 0.000000E+00 -E_domain_decomp_c4_dc12_e1 111 1 63 1 -0.000000E+00 -E_domain_decomp_c5_dc1_e1 112 113 52 1 0.000000E+00 -E_domain_decomp_c5_dc2_e1 113 114 53 1 0.000000E+00 -E_domain_decomp_c5_dc3_e1 114 115 54 1 0.000000E+00 -E_domain_decomp_c5_dc4_e1 115 116 55 1 0.000000E+00 -E_domain_decomp_c5_dc5_e1 116 117 56 1 5.000000E-01 -E_domain_decomp_c5_dc6_e1 117 118 57 1 1.000000E+00 -E_domain_decomp_c5_dc7_e1 118 119 58 1 0.000000E+00 -E_domain_decomp_c5_dc8_e1 119 120 59 1 0.000000E+00 -E_domain_decomp_c5_dc9_e1 120 121 60 1 0.000000E+00 -E_domain_decomp_c5_dc10_e1 121 122 61 1 -0.000000E+00 -E_domain_decomp_c5_dc11_e1 122 123 62 1 1.000000E+00 -E_domain_decomp_c5_dc12_e1 123 1 63 1 -0.000000E+00 -E_domain_decomp_c6_dc1_e1 124 125 52 1 0.000000E+00 -E_domain_decomp_c6_dc2_e1 125 126 53 1 0.000000E+00 -E_domain_decomp_c6_dc3_e1 126 127 54 1 0.000000E+00 -E_domain_decomp_c6_dc4_e1 127 128 55 1 0.000000E+00 -E_domain_decomp_c6_dc5_e1 128 129 56 1 -5.000000E-01 -E_domain_decomp_c6_dc6_e1 129 130 57 1 1.000000E+00 -E_domain_decomp_c6_dc7_e1 130 131 58 1 0.000000E+00 -E_domain_decomp_c6_dc8_e1 131 132 59 1 0.000000E+00 -E_domain_decomp_c6_dc9_e1 132 133 60 1 0.000000E+00 -E_domain_decomp_c6_dc10_e1 133 134 61 1 -0.000000E+00 -E_domain_decomp_c6_dc11_e1 134 135 62 1 1.000000E+00 -E_domain_decomp_c6_dc12_e1 135 1 63 1 -0.000000E+00 -E_domain_decomp_c7_dc1_e1 136 137 52 1 0.000000E+00 -E_domain_decomp_c7_dc2_e1 137 138 53 1 0.000000E+00 -E_domain_decomp_c7_dc3_e1 138 139 54 1 0.000000E+00 -E_domain_decomp_c7_dc4_e1 139 140 55 1 0.000000E+00 -E_domain_decomp_c7_dc5_e1 140 141 56 1 0.000000E+00 -E_domain_decomp_c7_dc6_e1 141 142 57 1 0.000000E+00 -E_domain_decomp_c7_dc7_e1 142 143 58 1 5.000000E-01 -E_domain_decomp_c7_dc8_e1 143 144 59 1 1.000000E+00 -E_domain_decomp_c7_dc9_e1 144 145 60 1 0.000000E+00 -E_domain_decomp_c7_dc10_e1 145 146 61 1 0.000000E+00 -E_domain_decomp_c7_dc11_e1 146 147 62 1 -0.000000E+00 -E_domain_decomp_c7_dc12_e1 147 1 63 1 1.000000E+00 -E_domain_decomp_c8_dc1_e1 148 149 52 1 0.000000E+00 -E_domain_decomp_c8_dc2_e1 149 150 53 1 0.000000E+00 -E_domain_decomp_c8_dc3_e1 150 151 54 1 0.000000E+00 -E_domain_decomp_c8_dc4_e1 151 152 55 1 0.000000E+00 -E_domain_decomp_c8_dc5_e1 152 153 56 1 0.000000E+00 -E_domain_decomp_c8_dc6_e1 153 154 57 1 0.000000E+00 -E_domain_decomp_c8_dc7_e1 154 155 58 1 -5.000000E-01 -E_domain_decomp_c8_dc8_e1 155 156 59 1 1.000000E+00 -E_domain_decomp_c8_dc9_e1 156 157 60 1 0.000000E+00 -E_domain_decomp_c8_dc10_e1 157 158 61 1 0.000000E+00 -E_domain_decomp_c8_dc11_e1 158 159 62 1 -0.000000E+00 -E_domain_decomp_c8_dc12_e1 159 1 63 1 1.000000E+00 -E_domain_decomp_c9_dc1_e1 160 161 52 1 0.000000E+00 -E_domain_decomp_c9_dc2_e1 161 162 53 1 0.000000E+00 -E_domain_decomp_c9_dc3_e1 162 163 54 1 0.000000E+00 -E_domain_decomp_c9_dc4_e1 163 164 55 1 0.000000E+00 -E_domain_decomp_c9_dc5_e1 164 165 56 1 0.000000E+00 -E_domain_decomp_c9_dc6_e1 165 166 57 1 0.000000E+00 -E_domain_decomp_c9_dc7_e1 166 167 58 1 0.000000E+00 -E_domain_decomp_c9_dc8_e1 167 168 59 1 -0.000000E+00 -E_domain_decomp_c9_dc9_e1 168 169 60 1 1.000000E+00 -E_domain_decomp_c9_dc10_e1 169 170 61 1 0.000000E+00 -E_domain_decomp_c9_dc11_e1 170 171 62 1 0.000000E+00 -E_domain_decomp_c9_dc12_e1 171 1 63 1 -0.000000E+00 -E_domain_decomp_c10_dc1_e1 172 173 52 1 0.000000E+00 -E_domain_decomp_c10_dc2_e1 173 174 53 1 0.000000E+00 -E_domain_decomp_c10_dc3_e1 174 175 54 1 0.000000E+00 -E_domain_decomp_c10_dc4_e1 175 176 55 1 0.000000E+00 -E_domain_decomp_c10_dc5_e1 176 177 56 1 0.000000E+00 -E_domain_decomp_c10_dc6_e1 177 178 57 1 0.000000E+00 -E_domain_decomp_c10_dc7_e1 178 179 58 1 0.000000E+00 -E_domain_decomp_c10_dc8_e1 179 180 59 1 0.000000E+00 -E_domain_decomp_c10_dc9_e1 180 181 60 1 -0.000000E+00 -E_domain_decomp_c10_dc10_e1 181 182 61 1 1.000000E+00 -E_domain_decomp_c10_dc11_e1 182 183 62 1 0.000000E+00 -E_domain_decomp_c10_dc12_e1 183 1 63 1 -0.000000E+00 -E_domain_decomp_c11_dc1_e1 184 185 52 1 0.000000E+00 -E_domain_decomp_c11_dc2_e1 185 186 53 1 0.000000E+00 -E_domain_decomp_c11_dc3_e1 186 187 54 1 0.000000E+00 -E_domain_decomp_c11_dc4_e1 187 188 55 1 0.000000E+00 -E_domain_decomp_c11_dc5_e1 188 189 56 1 0.000000E+00 -E_domain_decomp_c11_dc6_e1 189 190 57 1 0.000000E+00 -E_domain_decomp_c11_dc7_e1 190 191 58 1 0.000000E+00 -E_domain_decomp_c11_dc8_e1 191 192 59 1 0.000000E+00 -E_domain_decomp_c11_dc9_e1 192 193 60 1 0.000000E+00 -E_domain_decomp_c11_dc10_e1 193 194 61 1 -0.000000E+00 -E_domain_decomp_c11_dc11_e1 194 195 62 1 1.000000E+00 -E_domain_decomp_c11_dc12_e1 195 1 63 1 -0.000000E+00 -E_domain_decomp_c12_dc1_e1 196 197 52 1 0.000000E+00 -E_domain_decomp_c12_dc2_e1 197 198 53 1 0.000000E+00 -E_domain_decomp_c12_dc3_e1 198 199 54 1 0.000000E+00 -E_domain_decomp_c12_dc4_e1 199 200 55 1 0.000000E+00 -E_domain_decomp_c12_dc5_e1 200 201 56 1 0.000000E+00 -E_domain_decomp_c12_dc6_e1 201 202 57 1 0.000000E+00 -E_domain_decomp_c12_dc7_e1 202 203 58 1 0.000000E+00 -E_domain_decomp_c12_dc8_e1 203 204 59 1 0.000000E+00 -E_domain_decomp_c12_dc9_e1 204 205 60 1 0.000000E+00 -E_domain_decomp_c12_dc10_e1 205 206 61 1 0.000000E+00 -E_domain_decomp_c12_dc11_e1 206 207 62 1 -0.000000E+00 -E_domain_decomp_c12_dc12_e1 207 1 63 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 52 Vmeas_domain_decomp_c1_e1 5.000000E-01 -F_domain_decomp_c2_dc1_e1 1 52 Vmeas_domain_decomp_c2_e1 -5.000000E-01 -F_domain_decomp_c3_dc1_e1 1 52 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc1_e1 1 52 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc1_e1 1 52 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc1_e1 1 52 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc1_e1 1 52 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc1_e1 1 52 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc1_e1 1 52 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc1_e1 1 52 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc1_e1 1 52 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc1_e1 1 52 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 53 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc2_e1 1 53 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c3_dc2_e1 1 53 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc2_e1 1 53 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc2_e1 1 53 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc2_e1 1 53 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc2_e1 1 53 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc2_e1 1 53 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc2_e1 1 53 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc2_e1 1 53 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc2_e1 1 53 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc2_e1 1 53 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc3_e1 1 54 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc3_e1 1 54 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc3_e1 1 54 Vmeas_domain_decomp_c3_e1 5.000000E-01 -F_domain_decomp_c4_dc3_e1 1 54 Vmeas_domain_decomp_c4_e1 -5.000000E-01 -F_domain_decomp_c5_dc3_e1 1 54 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc3_e1 1 54 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc3_e1 1 54 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc3_e1 1 54 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc3_e1 1 54 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc3_e1 1 54 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc3_e1 1 54 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc3_e1 1 54 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc4_e1 1 55 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc4_e1 1 55 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc4_e1 1 55 Vmeas_domain_decomp_c3_e1 1.000000E+00 -F_domain_decomp_c4_dc4_e1 1 55 Vmeas_domain_decomp_c4_e1 1.000000E+00 -F_domain_decomp_c5_dc4_e1 1 55 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc4_e1 1 55 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc4_e1 1 55 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc4_e1 1 55 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc4_e1 1 55 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc4_e1 1 55 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc4_e1 1 55 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc4_e1 1 55 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc5_e1 1 56 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc5_e1 1 56 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc5_e1 1 56 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc5_e1 1 56 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc5_e1 1 56 Vmeas_domain_decomp_c5_e1 5.000000E-01 -F_domain_decomp_c6_dc5_e1 1 56 Vmeas_domain_decomp_c6_e1 -5.000000E-01 -F_domain_decomp_c7_dc5_e1 1 56 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc5_e1 1 56 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc5_e1 1 56 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc5_e1 1 56 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc5_e1 1 56 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc5_e1 1 56 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc6_e1 1 57 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc6_e1 1 57 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc6_e1 1 57 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc6_e1 1 57 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc6_e1 1 57 Vmeas_domain_decomp_c5_e1 1.000000E+00 -F_domain_decomp_c6_dc6_e1 1 57 Vmeas_domain_decomp_c6_e1 1.000000E+00 -F_domain_decomp_c7_dc6_e1 1 57 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc6_e1 1 57 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc6_e1 1 57 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc6_e1 1 57 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc6_e1 1 57 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc6_e1 1 57 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc7_e1 1 58 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc7_e1 1 58 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc7_e1 1 58 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc7_e1 1 58 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc7_e1 1 58 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc7_e1 1 58 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc7_e1 1 58 Vmeas_domain_decomp_c7_e1 5.000000E-01 -F_domain_decomp_c8_dc7_e1 1 58 Vmeas_domain_decomp_c8_e1 -5.000000E-01 -F_domain_decomp_c9_dc7_e1 1 58 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc7_e1 1 58 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc7_e1 1 58 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc7_e1 1 58 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc8_e1 1 59 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc8_e1 1 59 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc8_e1 1 59 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc8_e1 1 59 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc8_e1 1 59 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc8_e1 1 59 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc8_e1 1 59 Vmeas_domain_decomp_c7_e1 1.000000E+00 -F_domain_decomp_c8_dc8_e1 1 59 Vmeas_domain_decomp_c8_e1 1.000000E+00 -F_domain_decomp_c9_dc8_e1 1 59 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc8_e1 1 59 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc8_e1 1 59 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc8_e1 1 59 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc9_e1 1 60 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc9_e1 1 60 Vmeas_domain_decomp_c2_e1 1.000000E+00 -F_domain_decomp_c3_dc9_e1 1 60 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc9_e1 1 60 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc9_e1 1 60 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc9_e1 1 60 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc9_e1 1 60 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc9_e1 1 60 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc9_e1 1 60 Vmeas_domain_decomp_c9_e1 1.000000E+00 -F_domain_decomp_c10_dc9_e1 1 60 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc9_e1 1 60 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc9_e1 1 60 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc10_e1 1 61 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc10_e1 1 61 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc10_e1 1 61 Vmeas_domain_decomp_c3_e1 1.000000E+00 -F_domain_decomp_c4_dc10_e1 1 61 Vmeas_domain_decomp_c4_e1 1.000000E+00 -F_domain_decomp_c5_dc10_e1 1 61 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc10_e1 1 61 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc10_e1 1 61 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc10_e1 1 61 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc10_e1 1 61 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc10_e1 1 61 Vmeas_domain_decomp_c10_e1 1.000000E+00 -F_domain_decomp_c11_dc10_e1 1 61 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc10_e1 1 61 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc11_e1 1 62 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc11_e1 1 62 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc11_e1 1 62 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc11_e1 1 62 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc11_e1 1 62 Vmeas_domain_decomp_c5_e1 1.000000E+00 -F_domain_decomp_c6_dc11_e1 1 62 Vmeas_domain_decomp_c6_e1 1.000000E+00 -F_domain_decomp_c7_dc11_e1 1 62 Vmeas_domain_decomp_c7_e1 0.000000E+00 -F_domain_decomp_c8_dc11_e1 1 62 Vmeas_domain_decomp_c8_e1 0.000000E+00 -F_domain_decomp_c9_dc11_e1 1 62 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc11_e1 1 62 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc11_e1 1 62 Vmeas_domain_decomp_c11_e1 1.000000E+00 -F_domain_decomp_c12_dc11_e1 1 62 Vmeas_domain_decomp_c12_e1 0.000000E+00 -F_domain_decomp_c1_dc12_e1 1 63 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc12_e1 1 63 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c3_dc12_e1 1 63 Vmeas_domain_decomp_c3_e1 0.000000E+00 -F_domain_decomp_c4_dc12_e1 1 63 Vmeas_domain_decomp_c4_e1 0.000000E+00 -F_domain_decomp_c5_dc12_e1 1 63 Vmeas_domain_decomp_c5_e1 0.000000E+00 -F_domain_decomp_c6_dc12_e1 1 63 Vmeas_domain_decomp_c6_e1 0.000000E+00 -F_domain_decomp_c7_dc12_e1 1 63 Vmeas_domain_decomp_c7_e1 1.000000E+00 -F_domain_decomp_c8_dc12_e1 1 63 Vmeas_domain_decomp_c8_e1 1.000000E+00 -F_domain_decomp_c9_dc12_e1 1 63 Vmeas_domain_decomp_c9_e1 0.000000E+00 -F_domain_decomp_c10_dc12_e1 1 63 Vmeas_domain_decomp_c10_e1 0.000000E+00 -F_domain_decomp_c11_dc12_e1 1 63 Vmeas_domain_decomp_c11_e1 0.000000E+00 -F_domain_decomp_c12_dc12_e1 1 63 Vmeas_domain_decomp_c12_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 40 220 -Vmeas_domain_decomp_c2_e2 41 232 -Vmeas_domain_decomp_c3_e2 42 244 -Vmeas_domain_decomp_c4_e2 43 256 -Vmeas_domain_decomp_c5_e2 44 268 -Vmeas_domain_decomp_c6_e2 45 280 -Vmeas_domain_decomp_c7_e2 46 292 -Vmeas_domain_decomp_c8_e2 47 304 -Vmeas_domain_decomp_c9_e2 48 316 -Vmeas_domain_decomp_c10_e2 49 328 -Vmeas_domain_decomp_c11_e2 50 340 -Vmeas_domain_decomp_c12_e2 51 352 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 220 221 208 1 5.000000E-01 -E_domain_decomp_c1_dc2_e2 221 222 209 1 1.000000E+00 -E_domain_decomp_c1_dc3_e2 222 223 210 1 0.000000E+00 -E_domain_decomp_c1_dc4_e2 223 224 211 1 0.000000E+00 -E_domain_decomp_c1_dc5_e2 224 225 212 1 0.000000E+00 -E_domain_decomp_c1_dc6_e2 225 226 213 1 0.000000E+00 -E_domain_decomp_c1_dc7_e2 226 227 214 1 0.000000E+00 -E_domain_decomp_c1_dc8_e2 227 228 215 1 -0.000000E+00 -E_domain_decomp_c1_dc9_e2 228 229 216 1 1.000000E+00 -E_domain_decomp_c1_dc10_e2 229 230 217 1 0.000000E+00 -E_domain_decomp_c1_dc11_e2 230 231 218 1 0.000000E+00 -E_domain_decomp_c1_dc12_e2 231 1 219 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e2 232 233 208 1 -5.000000E-01 -E_domain_decomp_c2_dc2_e2 233 234 209 1 1.000000E+00 -E_domain_decomp_c2_dc3_e2 234 235 210 1 0.000000E+00 -E_domain_decomp_c2_dc4_e2 235 236 211 1 0.000000E+00 -E_domain_decomp_c2_dc5_e2 236 237 212 1 0.000000E+00 -E_domain_decomp_c2_dc6_e2 237 238 213 1 0.000000E+00 -E_domain_decomp_c2_dc7_e2 238 239 214 1 0.000000E+00 -E_domain_decomp_c2_dc8_e2 239 240 215 1 -0.000000E+00 -E_domain_decomp_c2_dc9_e2 240 241 216 1 1.000000E+00 -E_domain_decomp_c2_dc10_e2 241 242 217 1 0.000000E+00 -E_domain_decomp_c2_dc11_e2 242 243 218 1 0.000000E+00 -E_domain_decomp_c2_dc12_e2 243 1 219 1 -0.000000E+00 -E_domain_decomp_c3_dc1_e2 244 245 208 1 0.000000E+00 -E_domain_decomp_c3_dc2_e2 245 246 209 1 0.000000E+00 -E_domain_decomp_c3_dc3_e2 246 247 210 1 5.000000E-01 -E_domain_decomp_c3_dc4_e2 247 248 211 1 1.000000E+00 -E_domain_decomp_c3_dc5_e2 248 249 212 1 0.000000E+00 -E_domain_decomp_c3_dc6_e2 249 250 213 1 0.000000E+00 -E_domain_decomp_c3_dc7_e2 250 251 214 1 0.000000E+00 -E_domain_decomp_c3_dc8_e2 251 252 215 1 0.000000E+00 -E_domain_decomp_c3_dc9_e2 252 253 216 1 -0.000000E+00 -E_domain_decomp_c3_dc10_e2 253 254 217 1 1.000000E+00 -E_domain_decomp_c3_dc11_e2 254 255 218 1 0.000000E+00 -E_domain_decomp_c3_dc12_e2 255 1 219 1 -0.000000E+00 -E_domain_decomp_c4_dc1_e2 256 257 208 1 0.000000E+00 -E_domain_decomp_c4_dc2_e2 257 258 209 1 0.000000E+00 -E_domain_decomp_c4_dc3_e2 258 259 210 1 -5.000000E-01 -E_domain_decomp_c4_dc4_e2 259 260 211 1 1.000000E+00 -E_domain_decomp_c4_dc5_e2 260 261 212 1 0.000000E+00 -E_domain_decomp_c4_dc6_e2 261 262 213 1 0.000000E+00 -E_domain_decomp_c4_dc7_e2 262 263 214 1 0.000000E+00 -E_domain_decomp_c4_dc8_e2 263 264 215 1 0.000000E+00 -E_domain_decomp_c4_dc9_e2 264 265 216 1 -0.000000E+00 -E_domain_decomp_c4_dc10_e2 265 266 217 1 1.000000E+00 -E_domain_decomp_c4_dc11_e2 266 267 218 1 0.000000E+00 -E_domain_decomp_c4_dc12_e2 267 1 219 1 -0.000000E+00 -E_domain_decomp_c5_dc1_e2 268 269 208 1 0.000000E+00 -E_domain_decomp_c5_dc2_e2 269 270 209 1 0.000000E+00 -E_domain_decomp_c5_dc3_e2 270 271 210 1 0.000000E+00 -E_domain_decomp_c5_dc4_e2 271 272 211 1 0.000000E+00 -E_domain_decomp_c5_dc5_e2 272 273 212 1 5.000000E-01 -E_domain_decomp_c5_dc6_e2 273 274 213 1 1.000000E+00 -E_domain_decomp_c5_dc7_e2 274 275 214 1 0.000000E+00 -E_domain_decomp_c5_dc8_e2 275 276 215 1 0.000000E+00 -E_domain_decomp_c5_dc9_e2 276 277 216 1 0.000000E+00 -E_domain_decomp_c5_dc10_e2 277 278 217 1 -0.000000E+00 -E_domain_decomp_c5_dc11_e2 278 279 218 1 1.000000E+00 -E_domain_decomp_c5_dc12_e2 279 1 219 1 -0.000000E+00 -E_domain_decomp_c6_dc1_e2 280 281 208 1 0.000000E+00 -E_domain_decomp_c6_dc2_e2 281 282 209 1 0.000000E+00 -E_domain_decomp_c6_dc3_e2 282 283 210 1 0.000000E+00 -E_domain_decomp_c6_dc4_e2 283 284 211 1 0.000000E+00 -E_domain_decomp_c6_dc5_e2 284 285 212 1 -5.000000E-01 -E_domain_decomp_c6_dc6_e2 285 286 213 1 1.000000E+00 -E_domain_decomp_c6_dc7_e2 286 287 214 1 0.000000E+00 -E_domain_decomp_c6_dc8_e2 287 288 215 1 0.000000E+00 -E_domain_decomp_c6_dc9_e2 288 289 216 1 0.000000E+00 -E_domain_decomp_c6_dc10_e2 289 290 217 1 -0.000000E+00 -E_domain_decomp_c6_dc11_e2 290 291 218 1 1.000000E+00 -E_domain_decomp_c6_dc12_e2 291 1 219 1 -0.000000E+00 -E_domain_decomp_c7_dc1_e2 292 293 208 1 0.000000E+00 -E_domain_decomp_c7_dc2_e2 293 294 209 1 0.000000E+00 -E_domain_decomp_c7_dc3_e2 294 295 210 1 0.000000E+00 -E_domain_decomp_c7_dc4_e2 295 296 211 1 0.000000E+00 -E_domain_decomp_c7_dc5_e2 296 297 212 1 0.000000E+00 -E_domain_decomp_c7_dc6_e2 297 298 213 1 0.000000E+00 -E_domain_decomp_c7_dc7_e2 298 299 214 1 5.000000E-01 -E_domain_decomp_c7_dc8_e2 299 300 215 1 1.000000E+00 -E_domain_decomp_c7_dc9_e2 300 301 216 1 0.000000E+00 -E_domain_decomp_c7_dc10_e2 301 302 217 1 0.000000E+00 -E_domain_decomp_c7_dc11_e2 302 303 218 1 -0.000000E+00 -E_domain_decomp_c7_dc12_e2 303 1 219 1 1.000000E+00 -E_domain_decomp_c8_dc1_e2 304 305 208 1 0.000000E+00 -E_domain_decomp_c8_dc2_e2 305 306 209 1 0.000000E+00 -E_domain_decomp_c8_dc3_e2 306 307 210 1 0.000000E+00 -E_domain_decomp_c8_dc4_e2 307 308 211 1 0.000000E+00 -E_domain_decomp_c8_dc5_e2 308 309 212 1 0.000000E+00 -E_domain_decomp_c8_dc6_e2 309 310 213 1 0.000000E+00 -E_domain_decomp_c8_dc7_e2 310 311 214 1 -5.000000E-01 -E_domain_decomp_c8_dc8_e2 311 312 215 1 1.000000E+00 -E_domain_decomp_c8_dc9_e2 312 313 216 1 0.000000E+00 -E_domain_decomp_c8_dc10_e2 313 314 217 1 0.000000E+00 -E_domain_decomp_c8_dc11_e2 314 315 218 1 -0.000000E+00 -E_domain_decomp_c8_dc12_e2 315 1 219 1 1.000000E+00 -E_domain_decomp_c9_dc1_e2 316 317 208 1 0.000000E+00 -E_domain_decomp_c9_dc2_e2 317 318 209 1 0.000000E+00 -E_domain_decomp_c9_dc3_e2 318 319 210 1 0.000000E+00 -E_domain_decomp_c9_dc4_e2 319 320 211 1 0.000000E+00 -E_domain_decomp_c9_dc5_e2 320 321 212 1 0.000000E+00 -E_domain_decomp_c9_dc6_e2 321 322 213 1 0.000000E+00 -E_domain_decomp_c9_dc7_e2 322 323 214 1 0.000000E+00 -E_domain_decomp_c9_dc8_e2 323 324 215 1 -0.000000E+00 -E_domain_decomp_c9_dc9_e2 324 325 216 1 1.000000E+00 -E_domain_decomp_c9_dc10_e2 325 326 217 1 0.000000E+00 -E_domain_decomp_c9_dc11_e2 326 327 218 1 0.000000E+00 -E_domain_decomp_c9_dc12_e2 327 1 219 1 -0.000000E+00 -E_domain_decomp_c10_dc1_e2 328 329 208 1 0.000000E+00 -E_domain_decomp_c10_dc2_e2 329 330 209 1 0.000000E+00 -E_domain_decomp_c10_dc3_e2 330 331 210 1 0.000000E+00 -E_domain_decomp_c10_dc4_e2 331 332 211 1 0.000000E+00 -E_domain_decomp_c10_dc5_e2 332 333 212 1 0.000000E+00 -E_domain_decomp_c10_dc6_e2 333 334 213 1 0.000000E+00 -E_domain_decomp_c10_dc7_e2 334 335 214 1 0.000000E+00 -E_domain_decomp_c10_dc8_e2 335 336 215 1 0.000000E+00 -E_domain_decomp_c10_dc9_e2 336 337 216 1 -0.000000E+00 -E_domain_decomp_c10_dc10_e2 337 338 217 1 1.000000E+00 -E_domain_decomp_c10_dc11_e2 338 339 218 1 0.000000E+00 -E_domain_decomp_c10_dc12_e2 339 1 219 1 -0.000000E+00 -E_domain_decomp_c11_dc1_e2 340 341 208 1 0.000000E+00 -E_domain_decomp_c11_dc2_e2 341 342 209 1 0.000000E+00 -E_domain_decomp_c11_dc3_e2 342 343 210 1 0.000000E+00 -E_domain_decomp_c11_dc4_e2 343 344 211 1 0.000000E+00 -E_domain_decomp_c11_dc5_e2 344 345 212 1 0.000000E+00 -E_domain_decomp_c11_dc6_e2 345 346 213 1 0.000000E+00 -E_domain_decomp_c11_dc7_e2 346 347 214 1 0.000000E+00 -E_domain_decomp_c11_dc8_e2 347 348 215 1 0.000000E+00 -E_domain_decomp_c11_dc9_e2 348 349 216 1 0.000000E+00 -E_domain_decomp_c11_dc10_e2 349 350 217 1 -0.000000E+00 -E_domain_decomp_c11_dc11_e2 350 351 218 1 1.000000E+00 -E_domain_decomp_c11_dc12_e2 351 1 219 1 -0.000000E+00 -E_domain_decomp_c12_dc1_e2 352 353 208 1 0.000000E+00 -E_domain_decomp_c12_dc2_e2 353 354 209 1 0.000000E+00 -E_domain_decomp_c12_dc3_e2 354 355 210 1 0.000000E+00 -E_domain_decomp_c12_dc4_e2 355 356 211 1 0.000000E+00 -E_domain_decomp_c12_dc5_e2 356 357 212 1 0.000000E+00 -E_domain_decomp_c12_dc6_e2 357 358 213 1 0.000000E+00 -E_domain_decomp_c12_dc7_e2 358 359 214 1 0.000000E+00 -E_domain_decomp_c12_dc8_e2 359 360 215 1 0.000000E+00 -E_domain_decomp_c12_dc9_e2 360 361 216 1 0.000000E+00 -E_domain_decomp_c12_dc10_e2 361 362 217 1 0.000000E+00 -E_domain_decomp_c12_dc11_e2 362 363 218 1 -0.000000E+00 -E_domain_decomp_c12_dc12_e2 363 1 219 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 208 Vmeas_domain_decomp_c1_e2 5.000000E-01 -F_domain_decomp_c2_dc1_e2 1 208 Vmeas_domain_decomp_c2_e2 -5.000000E-01 -F_domain_decomp_c3_dc1_e2 1 208 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc1_e2 1 208 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc1_e2 1 208 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc1_e2 1 208 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc1_e2 1 208 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc1_e2 1 208 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc1_e2 1 208 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc1_e2 1 208 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc1_e2 1 208 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc1_e2 1 208 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 209 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc2_e2 1 209 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c3_dc2_e2 1 209 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc2_e2 1 209 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc2_e2 1 209 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc2_e2 1 209 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc2_e2 1 209 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc2_e2 1 209 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc2_e2 1 209 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc2_e2 1 209 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc2_e2 1 209 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc2_e2 1 209 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc3_e2 1 210 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc3_e2 1 210 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc3_e2 1 210 Vmeas_domain_decomp_c3_e2 5.000000E-01 -F_domain_decomp_c4_dc3_e2 1 210 Vmeas_domain_decomp_c4_e2 -5.000000E-01 -F_domain_decomp_c5_dc3_e2 1 210 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc3_e2 1 210 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc3_e2 1 210 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc3_e2 1 210 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc3_e2 1 210 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc3_e2 1 210 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc3_e2 1 210 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc3_e2 1 210 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc4_e2 1 211 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc4_e2 1 211 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc4_e2 1 211 Vmeas_domain_decomp_c3_e2 1.000000E+00 -F_domain_decomp_c4_dc4_e2 1 211 Vmeas_domain_decomp_c4_e2 1.000000E+00 -F_domain_decomp_c5_dc4_e2 1 211 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc4_e2 1 211 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc4_e2 1 211 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc4_e2 1 211 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc4_e2 1 211 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc4_e2 1 211 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc4_e2 1 211 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc4_e2 1 211 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc5_e2 1 212 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc5_e2 1 212 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc5_e2 1 212 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc5_e2 1 212 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc5_e2 1 212 Vmeas_domain_decomp_c5_e2 5.000000E-01 -F_domain_decomp_c6_dc5_e2 1 212 Vmeas_domain_decomp_c6_e2 -5.000000E-01 -F_domain_decomp_c7_dc5_e2 1 212 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc5_e2 1 212 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc5_e2 1 212 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc5_e2 1 212 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc5_e2 1 212 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc5_e2 1 212 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc6_e2 1 213 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc6_e2 1 213 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc6_e2 1 213 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc6_e2 1 213 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc6_e2 1 213 Vmeas_domain_decomp_c5_e2 1.000000E+00 -F_domain_decomp_c6_dc6_e2 1 213 Vmeas_domain_decomp_c6_e2 1.000000E+00 -F_domain_decomp_c7_dc6_e2 1 213 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc6_e2 1 213 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc6_e2 1 213 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc6_e2 1 213 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc6_e2 1 213 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc6_e2 1 213 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc7_e2 1 214 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc7_e2 1 214 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc7_e2 1 214 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc7_e2 1 214 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc7_e2 1 214 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc7_e2 1 214 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc7_e2 1 214 Vmeas_domain_decomp_c7_e2 5.000000E-01 -F_domain_decomp_c8_dc7_e2 1 214 Vmeas_domain_decomp_c8_e2 -5.000000E-01 -F_domain_decomp_c9_dc7_e2 1 214 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc7_e2 1 214 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc7_e2 1 214 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc7_e2 1 214 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc8_e2 1 215 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc8_e2 1 215 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc8_e2 1 215 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc8_e2 1 215 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc8_e2 1 215 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc8_e2 1 215 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc8_e2 1 215 Vmeas_domain_decomp_c7_e2 1.000000E+00 -F_domain_decomp_c8_dc8_e2 1 215 Vmeas_domain_decomp_c8_e2 1.000000E+00 -F_domain_decomp_c9_dc8_e2 1 215 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc8_e2 1 215 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc8_e2 1 215 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc8_e2 1 215 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc9_e2 1 216 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc9_e2 1 216 Vmeas_domain_decomp_c2_e2 1.000000E+00 -F_domain_decomp_c3_dc9_e2 1 216 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc9_e2 1 216 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc9_e2 1 216 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc9_e2 1 216 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc9_e2 1 216 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc9_e2 1 216 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc9_e2 1 216 Vmeas_domain_decomp_c9_e2 1.000000E+00 -F_domain_decomp_c10_dc9_e2 1 216 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc9_e2 1 216 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc9_e2 1 216 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc10_e2 1 217 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc10_e2 1 217 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc10_e2 1 217 Vmeas_domain_decomp_c3_e2 1.000000E+00 -F_domain_decomp_c4_dc10_e2 1 217 Vmeas_domain_decomp_c4_e2 1.000000E+00 -F_domain_decomp_c5_dc10_e2 1 217 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc10_e2 1 217 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc10_e2 1 217 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc10_e2 1 217 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc10_e2 1 217 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc10_e2 1 217 Vmeas_domain_decomp_c10_e2 1.000000E+00 -F_domain_decomp_c11_dc10_e2 1 217 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc10_e2 1 217 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc11_e2 1 218 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc11_e2 1 218 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc11_e2 1 218 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc11_e2 1 218 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc11_e2 1 218 Vmeas_domain_decomp_c5_e2 1.000000E+00 -F_domain_decomp_c6_dc11_e2 1 218 Vmeas_domain_decomp_c6_e2 1.000000E+00 -F_domain_decomp_c7_dc11_e2 1 218 Vmeas_domain_decomp_c7_e2 0.000000E+00 -F_domain_decomp_c8_dc11_e2 1 218 Vmeas_domain_decomp_c8_e2 0.000000E+00 -F_domain_decomp_c9_dc11_e2 1 218 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc11_e2 1 218 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc11_e2 1 218 Vmeas_domain_decomp_c11_e2 1.000000E+00 -F_domain_decomp_c12_dc11_e2 1 218 Vmeas_domain_decomp_c12_e2 0.000000E+00 -F_domain_decomp_c1_dc12_e2 1 219 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc12_e2 1 219 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c3_dc12_e2 1 219 Vmeas_domain_decomp_c3_e2 0.000000E+00 -F_domain_decomp_c4_dc12_e2 1 219 Vmeas_domain_decomp_c4_e2 0.000000E+00 -F_domain_decomp_c5_dc12_e2 1 219 Vmeas_domain_decomp_c5_e2 0.000000E+00 -F_domain_decomp_c6_dc12_e2 1 219 Vmeas_domain_decomp_c6_e2 0.000000E+00 -F_domain_decomp_c7_dc12_e2 1 219 Vmeas_domain_decomp_c7_e2 1.000000E+00 -F_domain_decomp_c8_dc12_e2 1 219 Vmeas_domain_decomp_c8_e2 1.000000E+00 -F_domain_decomp_c9_dc12_e2 1 219 Vmeas_domain_decomp_c9_e2 0.000000E+00 -F_domain_decomp_c10_dc12_e2 1 219 Vmeas_domain_decomp_c10_e2 0.000000E+00 -F_domain_decomp_c11_dc12_e2 1 219 Vmeas_domain_decomp_c11_e2 0.000000E+00 -F_domain_decomp_c12_dc12_e2 1 219 Vmeas_domain_decomp_c12_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 52 365 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 365 1 364 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 364 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 208 367 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 367 1 366 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 366 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 364 368 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 366 369 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 368 1 370 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 369 1 371 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 371 1 372 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 370 1 373 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 371 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 370 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 372 374 364 1 2.000000E+00 -E_m_pz_d1_m1_e2 374 1 368 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 373 375 366 1 2.000000E+00 -E_m_mz_d1_m1_e2 375 1 369 1 -1.000000E+00 -* -* DOMAIN 2 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e1 53 377 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e1 377 1 376 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e1 1 376 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d2_c1_e2 209 379 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d2_c1_m1_e2 379 1 378 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d2_c1_m1_e2 1 378 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d2_m1_e1 376 380 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d2_m1_e2 378 381 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d2_m1_e1 380 1 382 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d2_m1_e2 381 1 383 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d2_m1_e1 383 1 384 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d2_m1_e2 382 1 385 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d2_m1_e1 383 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d2_m1_e2 382 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d2_m1_e1 384 386 376 1 2.000000E+00 -E_m_pz_d2_m1_e2 386 1 380 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d2_m1_e1 385 387 378 1 2.000000E+00 -E_m_mz_d2_m1_e2 387 1 381 1 -1.000000E+00 -* -* DOMAIN 3 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d3_c1_e1 54 389 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d3_c1_m1_e1 389 1 388 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d3_c1_m1_e1 1 388 Vmeas_mode_decomp_d3_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d3_c1_e2 210 391 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d3_c1_m1_e2 391 1 390 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d3_c1_m1_e2 1 390 Vmeas_mode_decomp_d3_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d3_m1_e1 388 392 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d3_m1_e2 390 393 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d3_m1_e1 392 1 394 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d3_m1_e2 393 1 395 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d3_m1_e1 395 1 396 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d3_m1_e2 394 1 397 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d3_m1_e1 395 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d3_m1_e2 394 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d3_m1_e1 396 398 388 1 2.000000E+00 -E_m_pz_d3_m1_e2 398 1 392 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d3_m1_e1 397 399 390 1 2.000000E+00 -E_m_mz_d3_m1_e2 399 1 393 1 -1.000000E+00 -* -* DOMAIN 4 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d4_c1_e1 55 401 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d4_c1_m1_e1 401 1 400 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d4_c1_m1_e1 1 400 Vmeas_mode_decomp_d4_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d4_c1_e2 211 403 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d4_c1_m1_e2 403 1 402 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d4_c1_m1_e2 1 402 Vmeas_mode_decomp_d4_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d4_m1_e1 400 404 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d4_m1_e2 402 405 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d4_m1_e1 404 1 406 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d4_m1_e2 405 1 407 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d4_m1_e1 407 1 408 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d4_m1_e2 406 1 409 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d4_m1_e1 407 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d4_m1_e2 406 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d4_m1_e1 408 410 400 1 2.000000E+00 -E_m_pz_d4_m1_e2 410 1 404 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d4_m1_e1 409 411 402 1 2.000000E+00 -E_m_mz_d4_m1_e2 411 1 405 1 -1.000000E+00 -* -* DOMAIN 5 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d5_c1_e1 56 413 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d5_c1_m1_e1 413 1 412 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d5_c1_m1_e1 1 412 Vmeas_mode_decomp_d5_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d5_c1_e2 212 415 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d5_c1_m1_e2 415 1 414 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d5_c1_m1_e2 1 414 Vmeas_mode_decomp_d5_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d5_m1_e1 412 416 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d5_m1_e2 414 417 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d5_m1_e1 416 1 418 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d5_m1_e2 417 1 419 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d5_m1_e1 419 1 420 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d5_m1_e2 418 1 421 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d5_m1_e1 419 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d5_m1_e2 418 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d5_m1_e1 420 422 412 1 2.000000E+00 -E_m_pz_d5_m1_e2 422 1 416 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d5_m1_e1 421 423 414 1 2.000000E+00 -E_m_mz_d5_m1_e2 423 1 417 1 -1.000000E+00 -* -* DOMAIN 6 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d6_c1_e1 57 425 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d6_c1_m1_e1 425 1 424 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d6_c1_m1_e1 1 424 Vmeas_mode_decomp_d6_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d6_c1_e2 213 427 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d6_c1_m1_e2 427 1 426 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d6_c1_m1_e2 1 426 Vmeas_mode_decomp_d6_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d6_m1_e1 424 428 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d6_m1_e2 426 429 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d6_m1_e1 428 1 430 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d6_m1_e2 429 1 431 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d6_m1_e1 431 1 432 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d6_m1_e2 430 1 433 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d6_m1_e1 431 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d6_m1_e2 430 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d6_m1_e1 432 434 424 1 2.000000E+00 -E_m_pz_d6_m1_e2 434 1 428 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d6_m1_e1 433 435 426 1 2.000000E+00 -E_m_mz_d6_m1_e2 435 1 429 1 -1.000000E+00 -* -* DOMAIN 7 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d7_c1_e1 58 437 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d7_c1_m1_e1 437 1 436 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d7_c1_m1_e1 1 436 Vmeas_mode_decomp_d7_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d7_c1_e2 214 439 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d7_c1_m1_e2 439 1 438 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d7_c1_m1_e2 1 438 Vmeas_mode_decomp_d7_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d7_m1_e1 436 440 1.194535E+02 -* -* Modal impedance: end2 -* -RZCm_d7_m1_e2 438 441 1.194535E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d7_m1_e1 440 1 442 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d7_m1_e2 441 1 443 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d7_m1_e1 443 1 444 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Delay line for negative z propagation -* -T_mz_d7_m1_e2 442 1 445 1 Z0= 1.194535E+02 TD= 4.039685E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d7_m1_e1 443 1 1.194535E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d7_m1_e2 442 1 1.194535E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d7_m1_e1 444 446 436 1 2.000000E+00 -E_m_pz_d7_m1_e2 446 1 440 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d7_m1_e1 445 447 438 1 2.000000E+00 -E_m_mz_d7_m1_e2 447 1 441 1 -1.000000E+00 -* -* DOMAIN 8 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d8_c1_e1 59 449 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d8_c1_m1_e1 449 1 448 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d8_c1_m1_e1 1 448 Vmeas_mode_decomp_d8_c1_e1 1.00000000E+00 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d8_c1_e2 215 451 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d8_c1_m1_e2 451 1 450 1 1.00000000E+00 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d8_c1_m1_e2 1 450 Vmeas_mode_decomp_d8_c1_e2 1.00000000E+00 -* -* Modal impedance: end1 -* -RZCm_d8_m1_e1 448 452 7.464194E+01 -* -* Modal impedance: end2 -* -RZCm_d8_m1_e2 450 453 7.464194E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d8_m1_e1 452 1 454 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d8_m1_e2 453 1 455 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d8_m1_e1 455 1 456 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Delay line for negative z propagation -* -T_mz_d8_m1_e2 454 1 457 1 Z0= 7.464194E+01 TD= 3.599548E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d8_m1_e1 455 1 7.464194E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d8_m1_e2 454 1 7.464194E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d8_m1_e1 456 458 448 1 2.000000E+00 -E_m_pz_d8_m1_e2 458 1 452 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d8_m1_e1 457 459 450 1 2.000000E+00 -E_m_mz_d8_m1_e2 459 1 453 1 -1.000000E+00 -* -* DOMAIN 9 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d9_c1_e1 60 464 -Vmeas_mode_decomp_d9_c2_e1 61 468 -Vmeas_mode_decomp_d9_c3_e1 62 472 -Vmeas_mode_decomp_d9_c4_e1 63 476 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d9_c1_m1_e1 464 465 460 1 4.99997010E-01 -E_mode_decomp_d9_c1_m2_e1 465 466 461 1 6.60299603E-01 -E_mode_decomp_d9_c1_m3_e1 466 467 462 1 -2.52110920E-01 -E_mode_decomp_d9_c1_m4_e1 467 1 463 1 5.00566867E-01 -E_mode_decomp_d9_c2_m1_e1 468 469 460 1 5.00000814E-01 -E_mode_decomp_d9_c2_m2_e1 469 470 461 1 2.52638434E-01 -E_mode_decomp_d9_c2_m3_e1 470 471 462 1 6.60216363E-01 -E_mode_decomp_d9_c2_m4_e1 471 1 463 1 -5.00372583E-01 -E_mode_decomp_d9_c3_m1_e1 472 473 460 1 5.00001652E-01 -E_mode_decomp_d9_c3_m2_e1 473 474 461 1 -6.60745021E-01 -E_mode_decomp_d9_c3_m3_e1 474 475 462 1 2.52713880E-01 -E_mode_decomp_d9_c3_m4_e1 475 1 463 1 4.99437438E-01 -E_mode_decomp_d9_c4_m1_e1 476 477 460 1 5.00000524E-01 -E_mode_decomp_d9_c4_m2_e1 477 478 461 1 -2.52179072E-01 -E_mode_decomp_d9_c4_m3_e1 478 479 462 1 -6.60825366E-01 -E_mode_decomp_d9_c4_m4_e1 479 1 463 1 -4.99622234E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d9_c1_m1_e1 1 460 Vmeas_mode_decomp_d9_c1_e1 4.99997010E-01 -F_mode_decomp_d9_c2_m1_e1 1 460 Vmeas_mode_decomp_d9_c2_e1 5.00000814E-01 -F_mode_decomp_d9_c3_m1_e1 1 460 Vmeas_mode_decomp_d9_c3_e1 5.00001652E-01 -F_mode_decomp_d9_c4_m1_e1 1 460 Vmeas_mode_decomp_d9_c4_e1 5.00000524E-01 -F_mode_decomp_d9_c1_m2_e1 1 461 Vmeas_mode_decomp_d9_c1_e1 6.60299603E-01 -F_mode_decomp_d9_c2_m2_e1 1 461 Vmeas_mode_decomp_d9_c2_e1 2.52638434E-01 -F_mode_decomp_d9_c3_m2_e1 1 461 Vmeas_mode_decomp_d9_c3_e1 -6.60745021E-01 -F_mode_decomp_d9_c4_m2_e1 1 461 Vmeas_mode_decomp_d9_c4_e1 -2.52179072E-01 -F_mode_decomp_d9_c1_m3_e1 1 462 Vmeas_mode_decomp_d9_c1_e1 -2.52110920E-01 -F_mode_decomp_d9_c2_m3_e1 1 462 Vmeas_mode_decomp_d9_c2_e1 6.60216363E-01 -F_mode_decomp_d9_c3_m3_e1 1 462 Vmeas_mode_decomp_d9_c3_e1 2.52713880E-01 -F_mode_decomp_d9_c4_m3_e1 1 462 Vmeas_mode_decomp_d9_c4_e1 -6.60825366E-01 -F_mode_decomp_d9_c1_m4_e1 1 463 Vmeas_mode_decomp_d9_c1_e1 5.00566867E-01 -F_mode_decomp_d9_c2_m4_e1 1 463 Vmeas_mode_decomp_d9_c2_e1 -5.00372583E-01 -F_mode_decomp_d9_c3_m4_e1 1 463 Vmeas_mode_decomp_d9_c3_e1 4.99437438E-01 -F_mode_decomp_d9_c4_m4_e1 1 463 Vmeas_mode_decomp_d9_c4_e1 -4.99622234E-01 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d9_c1_e2 216 484 -Vmeas_mode_decomp_d9_c2_e2 217 488 -Vmeas_mode_decomp_d9_c3_e2 218 492 -Vmeas_mode_decomp_d9_c4_e2 219 496 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d9_c1_m1_e2 484 485 480 1 4.99997010E-01 -E_mode_decomp_d9_c1_m2_e2 485 486 481 1 6.60299603E-01 -E_mode_decomp_d9_c1_m3_e2 486 487 482 1 -2.52110920E-01 -E_mode_decomp_d9_c1_m4_e2 487 1 483 1 5.00566867E-01 -E_mode_decomp_d9_c2_m1_e2 488 489 480 1 5.00000814E-01 -E_mode_decomp_d9_c2_m2_e2 489 490 481 1 2.52638434E-01 -E_mode_decomp_d9_c2_m3_e2 490 491 482 1 6.60216363E-01 -E_mode_decomp_d9_c2_m4_e2 491 1 483 1 -5.00372583E-01 -E_mode_decomp_d9_c3_m1_e2 492 493 480 1 5.00001652E-01 -E_mode_decomp_d9_c3_m2_e2 493 494 481 1 -6.60745021E-01 -E_mode_decomp_d9_c3_m3_e2 494 495 482 1 2.52713880E-01 -E_mode_decomp_d9_c3_m4_e2 495 1 483 1 4.99437438E-01 -E_mode_decomp_d9_c4_m1_e2 496 497 480 1 5.00000524E-01 -E_mode_decomp_d9_c4_m2_e2 497 498 481 1 -2.52179072E-01 -E_mode_decomp_d9_c4_m3_e2 498 499 482 1 -6.60825366E-01 -E_mode_decomp_d9_c4_m4_e2 499 1 483 1 -4.99622234E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d9_c1_m1_e2 1 480 Vmeas_mode_decomp_d9_c1_e2 4.99997010E-01 -F_mode_decomp_d9_c2_m1_e2 1 480 Vmeas_mode_decomp_d9_c2_e2 5.00000814E-01 -F_mode_decomp_d9_c3_m1_e2 1 480 Vmeas_mode_decomp_d9_c3_e2 5.00001652E-01 -F_mode_decomp_d9_c4_m1_e2 1 480 Vmeas_mode_decomp_d9_c4_e2 5.00000524E-01 -F_mode_decomp_d9_c1_m2_e2 1 481 Vmeas_mode_decomp_d9_c1_e2 6.60299603E-01 -F_mode_decomp_d9_c2_m2_e2 1 481 Vmeas_mode_decomp_d9_c2_e2 2.52638434E-01 -F_mode_decomp_d9_c3_m2_e2 1 481 Vmeas_mode_decomp_d9_c3_e2 -6.60745021E-01 -F_mode_decomp_d9_c4_m2_e2 1 481 Vmeas_mode_decomp_d9_c4_e2 -2.52179072E-01 -F_mode_decomp_d9_c1_m3_e2 1 482 Vmeas_mode_decomp_d9_c1_e2 -2.52110920E-01 -F_mode_decomp_d9_c2_m3_e2 1 482 Vmeas_mode_decomp_d9_c2_e2 6.60216363E-01 -F_mode_decomp_d9_c3_m3_e2 1 482 Vmeas_mode_decomp_d9_c3_e2 2.52713880E-01 -F_mode_decomp_d9_c4_m3_e2 1 482 Vmeas_mode_decomp_d9_c4_e2 -6.60825366E-01 -F_mode_decomp_d9_c1_m4_e2 1 483 Vmeas_mode_decomp_d9_c1_e2 5.00566867E-01 -F_mode_decomp_d9_c2_m4_e2 1 483 Vmeas_mode_decomp_d9_c2_e2 -5.00372583E-01 -F_mode_decomp_d9_c3_m4_e2 1 483 Vmeas_mode_decomp_d9_c3_e2 4.99437438E-01 -F_mode_decomp_d9_c4_m4_e2 1 483 Vmeas_mode_decomp_d9_c4_e2 -4.99622234E-01 -* -* Modal impedance: end1 -* -RZCm_d9_m1_e1 460 500 9.322448E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m1_e2 480 501 9.322448E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m1_e1 500 1 502 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m1_e2 501 1 503 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m1_e1 503 1 504 1 Z0= 9.322448E+01 TD= 3.471226E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m1_e2 502 1 505 1 Z0= 9.322448E+01 TD= 3.471226E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m1_e1 503 1 9.322448E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m1_e2 502 1 9.322448E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m1_e1 504 506 460 1 2.000000E+00 -E_m_pz_d9_m1_e2 506 1 500 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m1_e1 505 507 480 1 2.000000E+00 -E_m_mz_d9_m1_e2 507 1 501 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m2_e1 461 508 4.294265E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m2_e2 481 509 4.294265E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m2_e1 508 1 510 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m2_e2 509 1 511 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m2_e1 511 1 512 1 Z0= 4.294265E+01 TD= 3.563291E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m2_e2 510 1 513 1 Z0= 4.294265E+01 TD= 3.563291E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m2_e1 511 1 4.294265E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m2_e2 510 1 4.294265E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m2_e1 512 514 461 1 2.000000E+00 -E_m_pz_d9_m2_e2 514 1 508 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m2_e1 513 515 481 1 2.000000E+00 -E_m_mz_d9_m2_e2 515 1 509 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m3_e1 462 516 4.294177E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m3_e2 482 517 4.294177E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m3_e1 516 1 518 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m3_e2 517 1 519 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m3_e1 519 1 520 1 Z0= 4.294177E+01 TD= 3.563298E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m3_e2 518 1 521 1 Z0= 4.294177E+01 TD= 3.563298E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m3_e1 519 1 4.294177E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m3_e2 518 1 4.294177E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m3_e1 520 522 462 1 2.000000E+00 -E_m_pz_d9_m3_e2 522 1 516 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m3_e1 521 523 482 1 2.000000E+00 -E_m_mz_d9_m3_e2 523 1 517 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d9_m4_e1 463 524 2.983334E+01 -* -* Modal impedance: end2 -* -RZCm_d9_m4_e2 483 525 2.983334E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d9_m4_e1 524 1 526 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d9_m4_e2 525 1 527 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d9_m4_e1 527 1 528 1 Z0= 2.983334E+01 TD= 3.608721E-09 -* -* Delay line for negative z propagation -* -T_mz_d9_m4_e2 526 1 529 1 Z0= 2.983334E+01 TD= 3.608721E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d9_m4_e1 527 1 2.983334E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d9_m4_e2 526 1 2.983334E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d9_m4_e1 528 530 463 1 2.000000E+00 -E_m_pz_d9_m4_e2 530 1 524 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d9_m4_e1 529 531 483 1 2.000000E+00 -E_m_mz_d9_m4_e2 531 1 525 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax.spice_model_spec b/EXAMPLE_MOD/SPICE/ZT_FD_Twinax.spice_model_spec deleted file mode 100644 index 8a97f4a..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax.spice_model_spec +++ /dev/null @@ -1,19 +0,0 @@ -# MOD_cable_lib_dir -../MOD_WEB_EXAMPLES/CABLE/ -# MOD_bundle_lib_dir -../MOD_WEB_EXAMPLES/BUNDLE/ -# MOD_spice_bundle_lib_dir -../MOD_WEB_EXAMPLES/SPICE/ -# spice_symbol_dir -../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ -# Specification for spice model of ZT_FD_Twinax -ZT_FD_twinax -# cable bundle length (m) -1.0 -# Incident field specification -0 amplitude (V/m) -0 0 ktheta kphi (degrees) -0 0 Etheta Ephi (degrees) -# Transfer Impedance Model -0 # number of transfer impedances to include in the model -No_validation_test \ No newline at end of file diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_LTspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_LTspice.lib deleted file mode 100644 index a27894b..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_LTspice.lib +++ /dev/null @@ -1,208 +0,0 @@ -* LTspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:twinax name:twinax_cable conductor number 1 -* node: 3 cable number: 1 type:twinax name:twinax_cable conductor number 2 -* node: 4 cable number: 1 type:twinax name:twinax_cable conductor number 3 -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:twinax name:twinax_cable conductor number 1 -* node: 6 cable number: 1 type:twinax name:twinax_cable conductor number 2 -* node: 7 cable number: 1 type:twinax name:twinax_cable conductor number 3 -* -.subckt ZT_FD_Twinax -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.092958E-02 -Rdc_c2_e1 3 9 5.092958E-02 -Rdc_c3_e1 4 1 5.000000E-02 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.092958E-02 -Rdc_c2_e2 6 11 5.092958E-02 -Rdc_c3_e2 7 1 5.000000E-02 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 1.000000E+00 -E_domain_decomp_c1_dc2_e1 15 1 13 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 1.000000E+00 -E_domain_decomp_c1_dc2_e2 21 1 19 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 26 -Vmeas_mode_decomp_d1_c2_e1 13 28 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 26 27 24 1 7.07106798E-01 -E_mode_decomp_d1_c1_m2_e1 27 1 25 1 -7.07106745E-01 -E_mode_decomp_d1_c2_m1_e1 28 29 24 1 7.07106765E-01 -E_mode_decomp_d1_c2_m2_e1 29 1 25 1 7.07106817E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 7.07106798E-01 -F_mode_decomp_d1_c2_m1_e1 1 24 Vmeas_mode_decomp_d1_c2_e1 7.07106765E-01 -F_mode_decomp_d1_c1_m2_e1 1 25 Vmeas_mode_decomp_d1_c1_e1 -7.07106745E-01 -F_mode_decomp_d1_c2_m2_e1 1 25 Vmeas_mode_decomp_d1_c2_e1 7.07106817E-01 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 32 -Vmeas_mode_decomp_d1_c2_e2 19 34 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 32 33 30 1 7.07106798E-01 -E_mode_decomp_d1_c1_m2_e2 33 1 31 1 -7.07106745E-01 -E_mode_decomp_d1_c2_m1_e2 34 35 30 1 7.07106765E-01 -E_mode_decomp_d1_c2_m2_e2 35 1 31 1 7.07106817E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 30 Vmeas_mode_decomp_d1_c1_e2 7.07106798E-01 -F_mode_decomp_d1_c2_m1_e2 1 30 Vmeas_mode_decomp_d1_c2_e2 7.07106765E-01 -F_mode_decomp_d1_c1_m2_e2 1 31 Vmeas_mode_decomp_d1_c1_e2 -7.07106745E-01 -F_mode_decomp_d1_c2_m2_e2 1 31 Vmeas_mode_decomp_d1_c2_e2 7.07106817E-01 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 36 1.106704E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 30 37 1.106704E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 36 1 38 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 37 1 39 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 39 1 40 1 Z0= 1.106704E+02 TD= 5.003461E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 38 1 41 1 Z0= 1.106704E+02 TD= 5.003461E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 39 1 1.106704E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 38 1 1.106704E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 40 42 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 42 1 36 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 41 43 30 1 2.000000E+00 -E_m_mz_d1_m1_e2 43 1 37 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m2_e1 25 44 5.041035E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m2_e2 31 45 5.041035E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m2_e1 44 1 46 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m2_e2 45 1 47 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m2_e1 47 1 48 1 Z0= 5.041035E+01 TD= 5.003461E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m2_e2 46 1 49 1 Z0= 5.041035E+01 TD= 5.003461E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m2_e1 47 1 5.041035E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m2_e2 46 1 5.041035E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m2_e1 48 50 25 1 2.000000E+00 -E_m_pz_d1_m2_e2 50 1 44 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m2_e1 49 51 31 1 2.000000E+00 -E_m_mz_d1_m2_e2 51 1 45 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_NGspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_NGspice.lib deleted file mode 100644 index 29dd48c..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_NGspice.lib +++ /dev/null @@ -1,208 +0,0 @@ -* Ngspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:twinax name:twinax_cable conductor number 1 -* node: 3 cable number: 1 type:twinax name:twinax_cable conductor number 2 -* node: 4 cable number: 1 type:twinax name:twinax_cable conductor number 3 -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:twinax name:twinax_cable conductor number 1 -* node: 6 cable number: 1 type:twinax name:twinax_cable conductor number 2 -* node: 7 cable number: 1 type:twinax name:twinax_cable conductor number 3 -* -.subckt ZT_FD_Twinax -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.092958E-02 -Rdc_c2_e1 3 9 5.092958E-02 -Rdc_c3_e1 4 1 5.000000E-02 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.092958E-02 -Rdc_c2_e2 6 11 5.092958E-02 -Rdc_c3_e2 7 1 5.000000E-02 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 1.000000E+00 -E_domain_decomp_c1_dc2_e1 15 1 13 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 1.000000E+00 -E_domain_decomp_c1_dc2_e2 21 1 19 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 26 -Vmeas_mode_decomp_d1_c2_e1 13 28 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 26 27 24 1 7.07106798E-01 -E_mode_decomp_d1_c1_m2_e1 27 1 25 1 -7.07106745E-01 -E_mode_decomp_d1_c2_m1_e1 28 29 24 1 7.07106765E-01 -E_mode_decomp_d1_c2_m2_e1 29 1 25 1 7.07106817E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 7.07106798E-01 -F_mode_decomp_d1_c2_m1_e1 1 24 Vmeas_mode_decomp_d1_c2_e1 7.07106765E-01 -F_mode_decomp_d1_c1_m2_e1 1 25 Vmeas_mode_decomp_d1_c1_e1 -7.07106745E-01 -F_mode_decomp_d1_c2_m2_e1 1 25 Vmeas_mode_decomp_d1_c2_e1 7.07106817E-01 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 32 -Vmeas_mode_decomp_d1_c2_e2 19 34 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 32 33 30 1 7.07106798E-01 -E_mode_decomp_d1_c1_m2_e2 33 1 31 1 -7.07106745E-01 -E_mode_decomp_d1_c2_m1_e2 34 35 30 1 7.07106765E-01 -E_mode_decomp_d1_c2_m2_e2 35 1 31 1 7.07106817E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 30 Vmeas_mode_decomp_d1_c1_e2 7.07106798E-01 -F_mode_decomp_d1_c2_m1_e2 1 30 Vmeas_mode_decomp_d1_c2_e2 7.07106765E-01 -F_mode_decomp_d1_c1_m2_e2 1 31 Vmeas_mode_decomp_d1_c1_e2 -7.07106745E-01 -F_mode_decomp_d1_c2_m2_e2 1 31 Vmeas_mode_decomp_d1_c2_e2 7.07106817E-01 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 36 1.106704E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 30 37 1.106704E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 36 1 38 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 37 1 39 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 39 1 40 1 Z0= 1.106704E+02 TD= 5.003461E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 38 1 41 1 Z0= 1.106704E+02 TD= 5.003461E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 39 1 1.106704E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 38 1 1.106704E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 40 42 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 42 1 36 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 41 43 30 1 2.000000E+00 -E_m_mz_d1_m1_e2 43 1 37 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m2_e1 25 44 5.041035E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m2_e2 31 45 5.041035E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m2_e1 44 1 46 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m2_e2 45 1 47 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m2_e1 47 1 48 1 Z0= 5.041035E+01 TD= 5.003461E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m2_e2 46 1 49 1 Z0= 5.041035E+01 TD= 5.003461E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m2_e1 47 1 5.041035E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m2_e2 46 1 5.041035E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m2_e1 48 50 25 1 2.000000E+00 -E_m_pz_d1_m2_e2 50 1 44 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m2_e1 49 51 31 1 2.000000E+00 -E_m_mz_d1_m2_e2 51 1 45 1 -1.000000E+00 -* -.ends -* diff --git a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_Pspice.lib b/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_Pspice.lib deleted file mode 100644 index 2a3ebc5..0000000 --- a/EXAMPLE_MOD/SPICE/ZT_FD_Twinax_Pspice.lib +++ /dev/null @@ -1,208 +0,0 @@ -* Pspice multi-conductor transmission line model -* Created by Spice cable model builder v2.3.1 -* -* Transmission line subcircuit -* -* -* End 1 nodes: -* -* node: 2 cable number: 1 type:twinax name:twinax_cable conductor number 1 -* node: 3 cable number: 1 type:twinax name:twinax_cable conductor number 2 -* node: 4 cable number: 1 type:twinax name:twinax_cable conductor number 3 -* -* End 2 nodes: -* -* node: 5 cable number: 1 type:twinax name:twinax_cable conductor number 1 -* node: 6 cable number: 1 type:twinax name:twinax_cable conductor number 2 -* node: 7 cable number: 1 type:twinax name:twinax_cable conductor number 3 -* -.subckt ZT_FD_Twinax -+ 2 3 4 -+ 5 6 7 -* -* D.C. RESISTANCE END 1 -* -Rdc_c1_e1 2 8 5.092958E-02 -Rdc_c2_e1 3 9 5.092958E-02 -Rdc_c3_e1 4 1 5.000000E-02 -* -* D.C. RESISTANCE END 2 -* -Rdc_c1_e2 5 10 5.092958E-02 -Rdc_c2_e2 6 11 5.092958E-02 -Rdc_c3_e2 7 1 5.000000E-02 -* -* DOMAIN TRANSFORMATION END 1 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e1 8 14 -Vmeas_domain_decomp_c2_e1 9 16 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e1 14 15 12 1 1.000000E+00 -E_domain_decomp_c1_dc2_e1 15 1 13 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e1 16 17 12 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 1.000000E+00 -F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 0.000000E+00 -F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 0.000000E+00 -F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 -* -* DOMAIN TRANSFORMATION END 2 -* -* -* Domain decomposition Voltage sources used for current sensing -* -Vmeas_domain_decomp_c1_e2 10 20 -Vmeas_domain_decomp_c2_e2 11 22 -* -* Domain decomposition Voltage controlled voltage sources (domain to conductor) -* -E_domain_decomp_c1_dc1_e2 20 21 18 1 1.000000E+00 -E_domain_decomp_c1_dc2_e2 21 1 19 1 -0.000000E+00 -E_domain_decomp_c2_dc1_e2 22 23 18 1 -0.000000E+00 -E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 -* -* Domain decomposition Current controlled current sources (conductor to domain) -* -F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 1.000000E+00 -F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 0.000000E+00 -F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 0.000000E+00 -F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 -* -* DOMAIN 1 -* -* -* Modal Decomposition -* -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e1 12 26 -Vmeas_mode_decomp_d1_c2_e1 13 28 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e1 26 27 24 1 7.07106798E-01 -E_mode_decomp_d1_c1_m2_e1 27 1 25 1 -7.07106745E-01 -E_mode_decomp_d1_c2_m1_e1 28 29 24 1 7.07106765E-01 -E_mode_decomp_d1_c2_m2_e1 29 1 25 1 7.07106817E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 7.07106798E-01 -F_mode_decomp_d1_c2_m1_e1 1 24 Vmeas_mode_decomp_d1_c2_e1 7.07106765E-01 -F_mode_decomp_d1_c1_m2_e1 1 25 Vmeas_mode_decomp_d1_c1_e1 -7.07106745E-01 -F_mode_decomp_d1_c2_m2_e1 1 25 Vmeas_mode_decomp_d1_c2_e1 7.07106817E-01 -* -* Modal decomposition Voltage sources used for current sensing -* -Vmeas_mode_decomp_d1_c1_e2 18 32 -Vmeas_mode_decomp_d1_c2_e2 19 34 -* -* Modal decomposition Voltage controlled voltage sources (mode to conductor) -* -E_mode_decomp_d1_c1_m1_e2 32 33 30 1 7.07106798E-01 -E_mode_decomp_d1_c1_m2_e2 33 1 31 1 -7.07106745E-01 -E_mode_decomp_d1_c2_m1_e2 34 35 30 1 7.07106765E-01 -E_mode_decomp_d1_c2_m2_e2 35 1 31 1 7.07106817E-01 -* -* Modal decomposition Current controlled current sources (conductor to mode) -* -F_mode_decomp_d1_c1_m1_e2 1 30 Vmeas_mode_decomp_d1_c1_e2 7.07106798E-01 -F_mode_decomp_d1_c2_m1_e2 1 30 Vmeas_mode_decomp_d1_c2_e2 7.07106765E-01 -F_mode_decomp_d1_c1_m2_e2 1 31 Vmeas_mode_decomp_d1_c1_e2 -7.07106745E-01 -F_mode_decomp_d1_c2_m2_e2 1 31 Vmeas_mode_decomp_d1_c2_e2 7.07106817E-01 -* -* Modal impedance: end1 -* -RZCm_d1_m1_e1 24 36 1.106704E+02 -* -* Modal impedance: end2 -* -RZCm_d1_m1_e2 30 37 1.106704E+02 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m1_e1 36 1 38 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m1_e2 37 1 39 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m1_e1 39 1 40 1 Z0= 1.106704E+02 TD= 5.003461E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m1_e2 38 1 41 1 Z0= 1.106704E+02 TD= 5.003461E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m1_e1 39 1 1.106704E+02 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m1_e2 38 1 1.106704E+02 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m1_e1 40 42 24 1 2.000000E+00 -E_m_pz_d1_m1_e2 42 1 36 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m1_e1 41 43 30 1 2.000000E+00 -E_m_mz_d1_m1_e2 43 1 37 1 -1.000000E+00 -* -* Modal impedance: end1 -* -RZCm_d1_m2_e1 25 44 5.041035E+01 -* -* Modal impedance: end2 -* -RZCm_d1_m2_e2 31 45 5.041035E+01 -* -* Modal frequency dependent voltage controlled voltage source : end1 -* -E_m_d1_m2_e1 44 1 46 1 1.000000E+00 -* -* Modal frequency dependent voltage controlled voltage source : end2 -* -E_m_d1_m2_e2 45 1 47 1 1.000000E+00 -* -* Delay line for positive z propagation -* -T_pz_d1_m2_e1 47 1 48 1 Z0= 5.041035E+01 TD= 5.003461E-09 -* -* Delay line for negative z propagation -* -T_mz_d1_m2_e2 46 1 49 1 Z0= 5.041035E+01 TD= 5.003461E-09 -* -* Modal impedances on modal positive z propagation delay lines -* -RZC_pz_d1_m2_e1 47 1 5.041035E+01 -* -* Modal impedances on modal negative z propagation delay lines -* -RZC_mz_d1_m2_e2 46 1 5.041035E+01 -* -* Delay line frequency dependent controlled sources for positive z propagation -* -E_m_pz_d1_m2_e1 48 50 25 1 2.000000E+00 -E_m_pz_d1_m2_e2 50 1 44 1 -1.000000E+00 -* -* Delay line frequency dependent controlled sources for negative z propagation -* -E_m_mz_d1_m2_e1 49 51 31 1 2.000000E+00 -E_m_mz_d1_m2_e2 51 1 45 1 -1.000000E+00 -* -.ends -* diff --git a/MOD_SPACE_CABLES/MOD_SPACE_CABLES.zip b/MOD_SPACE_CABLES/MOD_SPACE_CABLES.zip new file mode 100644 index 0000000..82ee6b5 Binary files /dev/null and b/MOD_SPACE_CABLES/MOD_SPACE_CABLES.zip differ diff --git a/MOD_WEB_EXAMPLES/BUNDLE/Coax_Gnd_EField.bundle b/MOD_WEB_EXAMPLES/BUNDLE/Coax_Gnd_EField.bundle new file mode 100644 index 0000000..7394ce5 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/Coax_Gnd_EField.bundle @@ -0,0 +1,172 @@ +v4.0.0 +Coax_Gnd_EField + 1 ! number of cables not including ground plane + 2 ! number of cables, cable name and x y coordinates follow... +coaxial_cable_02 + 0.0000000000000000 2.0000000000000000E-002 0.0000000000000000 x y coordinates and angle of cable +ground_plane + 0.0000000000000000 0.0000000000000000 90.000000000000000 x y coordinates and angle of ground plane + 6.1232339957367660E-017 1.0000000000000000 ground plane normal direction + 1 orientation of cables wrt ground plane + 3 # total number of conductors + 2 # total number of external conductors + 2 # dimension of the matrix system characterising the MTL propagation + 2 # number of domains + Domain number 1 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 1 + 2 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 2.50552594E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 1.06578826E-10 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.5055259369907356E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 10000000.000000000 # w normalisation constant + 2 # a order, a coefficients follow below: + 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + Domain number 2 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 2 + 3 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 6.60723411E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 1.68398764E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 6.6072341066465837E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.6839876385366454E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Global current domain transformation matrix, [MI] + 2 Dimension of [MI] + 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 + # Global voltage domain transformation matrix, [MV] + 2 Dimension of [MV] + 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 1.00000000E+00 + # Global domain based inductance matrix, [L] + 2 Dimension of [L] + 2.50552594E-07 0.00000000E+00 + 0.00000000E+00 6.60723411E-07 + # Global domain based capacitance matrix, [C] + 2 Dimension of [C] + 1.06578826E-10 0.00000000E+00 + 0.00000000E+00 1.68398764E-11 + Global domain based Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.5055259369907356E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 6.6072341066465837E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Global domain based Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 10000000.000000000 # w normalisation constant + 2 # a order, a coefficients follow below: + 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.6839876385366454E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor impedance models + 1 # Conductor impedance model type + 4.2000000000000002E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 1.4700000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 7.2179112513331222E-006 # shield thickness + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.29999999999999999 1.0000000000000000E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + 0 # Conductor impedance model type + # conductor x y positions + 0.0000000000000000 2.0000000000000000E-002 + 0.0000000000000000 2.0000000000000000E-002 + 0.0000000000000000 0.0000000000000000 +is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc + F 0 1 1 1 2 + T 1 2 2 1 3 + F 0 2 3 2 3 + # Conductor labels + Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire + Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield + Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane diff --git a/MOD_WEB_EXAMPLES/BUNDLE/Coax_Gnd_EField.bundle_spec b/MOD_WEB_EXAMPLES/BUNDLE/Coax_Gnd_EField.bundle_spec new file mode 100644 index 0000000..a51c33e --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/Coax_Gnd_EField.bundle_spec @@ -0,0 +1,9 @@ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +1 #Number of cables in bundle, cable list follows +coaxial_cable_02 +0.0 0.02 0 +ground_plane +no_laplace diff --git a/MOD_WEB_EXAMPLES/BUNDLE/FD_2_Wire.bundle b/MOD_WEB_EXAMPLES/BUNDLE/FD_2_Wire.bundle new file mode 100644 index 0000000..6368acb --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/FD_2_Wire.bundle @@ -0,0 +1,91 @@ +v4.0.0 +FD_2_Wire + 2 ! number of cables not including ground plane + 2 ! number of cables, cable name and x y coordinates follow... +single_wire + 3.0000000000000001E-003 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable +single_wire + 0.0000000000000000 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable +no_ground_plane + 2 # total number of conductors + 2 # total number of external conductors + 1 # dimension of the matrix system characterising the MTL propagation + 1 # number of domains + Domain number 1 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 1 + 2 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 1.10268615E-06 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 1.00903603E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.1026861492333964E-006 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.0090360315349812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Global current domain transformation matrix, [MI] + 1 Dimension of [MI] + 1.00000000E+00 + # Global voltage domain transformation matrix, [MV] + 1 Dimension of [MV] + 1.00000000E+00 + # Global domain based inductance matrix, [L] + 1 Dimension of [L] + 1.10268615E-06 + # Global domain based capacitance matrix, [C] + 1 Dimension of [C] + 1.00903603E-11 + Global domain based Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.1026861492333964E-006 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Global domain based Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.0090360315349812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor impedance models + 1 # Conductor impedance model type + 1.9050000000000000E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 1.9050000000000000E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + # conductor x y positions + 3.0000000000000001E-003 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 +is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc + F 0 1 1 1 2 + F 0 1 2 2 2 + # Conductor labels + Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire + Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire diff --git a/MOD_WEB_EXAMPLES/BUNDLE/FD_2_Wire.bundle_spec b/MOD_WEB_EXAMPLES/BUNDLE/FD_2_Wire.bundle_spec new file mode 100644 index 0000000..35159c8 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/FD_2_Wire.bundle_spec @@ -0,0 +1,11 @@ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +2 #Number of cables in bundle, cable list follows +single_wire +3.0e-3 0.0 0.0 +single_wire +0.0 0.0 0.0 +no_ground_plane +no_laplace diff --git a/MOD_WEB_EXAMPLES/BUNDLE/FD_ZT_Spacewire.bundle b/MOD_WEB_EXAMPLES/BUNDLE/FD_ZT_Spacewire.bundle new file mode 100644 index 0000000..afd1bd2 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/FD_ZT_Spacewire.bundle @@ -0,0 +1,2385 @@ +v4.0.0 +FD_ZT_Spacewire + 1 ! number of cables not including ground plane + 1 ! number of cables, cable name and x y coordinates follow... +spacewire + 0.0000000000000000 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable +no_ground_plane + 13 # total number of conductors + 1 # total number of external conductors + 12 # dimension of the matrix system characterising the MTL propagation + 9 # number of domains + Domain number 1 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 1 + 2 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 4.82554527E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 2 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 2 + 9 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 2.68677221E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 3 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 3 + 3 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 4.82554527E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 4 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 4 + 10 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 2.68677221E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 5 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 5 + 4 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 4.82554527E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 6 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 6 + 11 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 2.68677221E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 7 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 7 + 5 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 4.82554527E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 8 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 8 + 12 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 2.68677221E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 9 + 5 number of conductors in this domain + terminal_conductor_list + 5 ! number of elements + 9 + 10 + 11 + 12 + 13 + Per-Unit-length Inductance Matrix, [L] + 4 Dimension of [L] + 1.84316340E-07 5.39918049E-08 3.13072143E-08 5.39881438E-08 + 5.39918049E-08 1.84319509E-07 5.39831349E-08 3.13087805E-08 + 3.13072143E-08 5.39831349E-08 1.84332861E-07 5.39800105E-08 + 5.39881438E-08 3.13087805E-08 5.39800105E-08 1.84326252E-07 + Per-Unit-length Capacitance Matrix, [C] + 4 Dimension of [C] + 8.10461294E-11 -2.09376538E-11 -1.93945500E-12 -2.09339121E-11 + -2.09376538E-11 8.10428561E-11 -2.09295921E-11 -1.94046442E-12 + -1.93945500E-12 -2.09295921E-11 8.10305676E-11 -2.09263826E-11 + -2.09339121E-11 -1.94046442E-12 -2.09263826E-11 8.10359177E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 4 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8431633950127736E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3991804942125718E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1307214294412737E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3988143811142774E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3991804942125718E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8431950926864761E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3983134865942856E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1308780454336411E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1307214294412737E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3983134865942856E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8433286095430542E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3980010475558271E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3988143811142774E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1308780454336411E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3980010475558271E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8432625193110204E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 4 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1046129434812118E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0937653783662812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9394550041484633E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0933912129944816E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0937653783662812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1042856062401348E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0929592068643566E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9404644230052613E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9394550041484633E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0929592068643566E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1030567551953170E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0926382619037890E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0933912129944816E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9404644230052613E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0926382619037890E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1035917699675775E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Global current domain transformation matrix, [MI] + 12 Dimension of [MI] + 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 + # Global voltage domain transformation matrix, [MV] + 12 Dimension of [MV] + 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 + # Global domain based inductance matrix, [L] + 12 Dimension of [L] + 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82554527E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 2.68677221E-07 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.84316340E-07 5.39918049E-08 3.13072143E-08 5.39881438E-08 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.39918049E-08 1.84319509E-07 5.39831349E-08 3.13087805E-08 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 3.13072143E-08 5.39831349E-08 1.84332861E-07 5.39800105E-08 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.39881438E-08 3.13087805E-08 5.39800105E-08 1.84326252E-07 + # Global domain based capacitance matrix, [C] + 12 Dimension of [C] + 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 3.38180465E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 4.82242002E-11 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 8.10461294E-11 -2.09376538E-11 -1.93945500E-12 -2.09339121E-11 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -2.09376538E-11 8.10428561E-11 -2.09295921E-11 -1.94046442E-12 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.93945500E-12 -2.09295921E-11 8.10305676E-11 -2.09263826E-11 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -2.09339121E-11 -1.94046442E-12 -2.09263826E-11 8.10359177E-11 + Global domain based Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 12 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 3 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 4 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 9 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 10 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 11 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 12 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 3 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 4 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 9 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 10 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 11 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 12 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 4 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 9 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 10 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 11 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 12 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 3 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 9 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 10 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 11 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 12 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 5 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # 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w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 8 10 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 8 11 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 8 12 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 9 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 9 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # 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w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 3 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 4 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 9 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0937653783662812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 10 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1042856062401348E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 11 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0929592068643566E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 10 12 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9404644230052613E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 3 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 4 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 9 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9394550041484633E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 10 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0929592068643566E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 11 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1030567551953170E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 11 12 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0926382619037890E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 3 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 4 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 5 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 6 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 7 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 8 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 9 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0933912129944816E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 10 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9404644230052613E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 11 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0926382619037890E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 12 12 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1035917699675775E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor impedance models + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 8.0000000000000002E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 5.8594000000000002E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 6.7910018908980910E-003 6.3516651586671768 131.85223712596317 714.73088207712362 1550.1604988129416 1509.1499548754166 617.70419490065785 + 5 # b order, b coefficients follow below: + 1.0000000000000000 20.715352684308218 112.30217945904732 243.56691527043952 237.12345747204483 97.056063856769896 + # conductor x y positions + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 +is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc + F 0 1 1 1 2 + F 0 2 2 1 9 + F 0 3 3 1 3 + F 0 4 4 1 10 + F 0 5 5 1 4 + F 0 6 6 1 11 + F 0 7 7 1 5 + F 0 8 8 1 12 + T 2 9 9 1 13 + T 4 9 10 2 13 + T 6 9 11 3 13 + T 8 9 12 4 13 + F 0 10 13 1 13 + # Conductor labels + Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 + Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 + Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 + Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 + Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 + Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 + Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 + Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 + Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 + Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 + Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 + Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 + Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield diff --git a/MOD_WEB_EXAMPLES/BUNDLE/FD_ZT_Spacewire.bundle_spec b/MOD_WEB_EXAMPLES/BUNDLE/FD_ZT_Spacewire.bundle_spec new file mode 100644 index 0000000..19bf715 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/FD_ZT_Spacewire.bundle_spec @@ -0,0 +1,9 @@ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +1 #Number of cables in bundle, cable list follows +spacewire +0.0 0.0 0 +no_ground_plane +no_laplace diff --git a/MOD_WEB_EXAMPLES/BUNDLE/Twisted_Pair_Over_Ground.bundle b/MOD_WEB_EXAMPLES/BUNDLE/Twisted_Pair_Over_Ground.bundle new file mode 100644 index 0000000..e2d6ff0 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/Twisted_Pair_Over_Ground.bundle @@ -0,0 +1,166 @@ +v4.0.0 +Twisted_Pair_Over_Ground + 1 ! number of cables not including ground plane + 2 ! number of cables, cable name and x y coordinates follow... +twisted_pair + 0.0000000000000000 4.0000000000000001E-003 0.0000000000000000 x y coordinates and angle of cable +ground_plane + 0.0000000000000000 0.0000000000000000 90.000000000000000 x y coordinates and angle of ground plane + 6.1232339957367660E-017 1.0000000000000000 ground plane normal direction + 1 orientation of cables wrt ground plane + 3 # total number of conductors + 2 # total number of external conductors + 2 # dimension of the matrix system characterising the MTL propagation + 2 # number of domains + Domain number 1 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 1 + 2 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 5.30708040E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 2.09653891E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3070804032283549E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.0965389093676046E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 2 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 2 + 3 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 6.30131112E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 1.76574372E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 6.3013111161292162E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.7657437246719178E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Global current domain transformation matrix, [MI] + 2 Dimension of [MI] + 5.00000000E-01 -5.00000000E-01 + 1.00000000E+00 1.00000000E+00 + # Global voltage domain transformation matrix, [MV] + 2 Dimension of [MV] + 1.00000000E+00 -1.00000000E+00 + 5.00000000E-01 5.00000000E-01 + # Global domain based inductance matrix, [L] + 2 Dimension of [L] + 5.30708040E-07 0.00000000E+00 + 0.00000000E+00 6.30131112E-07 + # Global domain based capacitance matrix, [C] + 2 Dimension of [C] + 2.09653891E-11 0.00000000E+00 + 0.00000000E+00 1.76574372E-11 + Global domain based Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3070804032283549E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 6.3013111161292162E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Global domain based Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.0965389093676046E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.7657437246719178E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor impedance models + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 0.0000000000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 0.0000000000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 0 # Conductor impedance model type + # conductor x y positions + 0.0000000000000000 4.0000000000000001E-003 + 0.0000000000000000 4.0000000000000001E-003 + 0.0000000000000000 0.0000000000000000 +is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc + F 0 1 1 1 2 + F 0 2 2 1 3 + F 0 2 3 2 3 + # Conductor labels + Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 + Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 + Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane diff --git a/MOD_WEB_EXAMPLES/BUNDLE/Twisted_Pair_Over_Ground.bundle_spec b/MOD_WEB_EXAMPLES/BUNDLE/Twisted_Pair_Over_Ground.bundle_spec new file mode 100644 index 0000000..c7b0fbf --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/Twisted_Pair_Over_Ground.bundle_spec @@ -0,0 +1,9 @@ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +1 #Number of cables in bundle, cable list follows +twisted_pair +0.0 4.0e-3 0 +ground_plane +use_laplace diff --git a/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_Coax.bundle b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_Coax.bundle new file mode 100644 index 0000000..6a19700 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_Coax.bundle @@ -0,0 +1,174 @@ +v4.0.0 +ZT_FD_Coax + 2 ! number of cables not including ground plane + 2 ! number of cables, cable name and x y coordinates follow... +bare_wire + 5.0000000000000001E-003 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable +coaxial_cable_01 + -5.0000000000000001E-003 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable +no_ground_plane + 3 # total number of conductors + 2 # total number of external conductors + 2 # dimension of the matrix system characterising the MTL propagation + 2 # number of domains + Domain number 1 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 2 + 3 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 2.50552594E-07 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 1.06578826E-10 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.5055259369907356E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 10000000.000000000 # w normalisation constant + 2 # a order, a coefficients follow below: + 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + Domain number 2 + 2 number of conductors in this domain + terminal_conductor_list + 2 ! number of elements + 1 + 3 + Per-Unit-length Inductance Matrix, [L] + 1 Dimension of [L] + 1.30449858E-06 + Per-Unit-length Capacitance Matrix, [C] + 1 Dimension of [C] + 8.52933132E-12 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.3044985756382986E-006 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.5293313218577504E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Global current domain transformation matrix, [MI] + 2 Dimension of [MI] + 0.00000000E+00 1.00000000E+00 + 1.00000000E+00 0.00000000E+00 + # Global voltage domain transformation matrix, [MV] + 2 Dimension of [MV] + 0.00000000E+00 1.00000000E+00 + 1.00000000E+00 0.00000000E+00 + # Global domain based inductance matrix, [L] + 2 Dimension of [L] + 2.50552594E-07 0.00000000E+00 + 0.00000000E+00 1.30449858E-06 + # Global domain based capacitance matrix, [C] + 2 Dimension of [C] + 1.06578826E-10 0.00000000E+00 + 0.00000000E+00 8.52933132E-12 + Global domain based Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.5055259369907356E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.3044985756382986E-006 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Global domain based Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 10000000.000000000 # w normalisation constant + 2 # a order, a coefficients follow below: + 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 0.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.5293313218577504E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor impedance models + 1 # Conductor impedance model type + 1.0000000000000000E-004 # conductor radius + 0.0000000000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 4.2000000000000002E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 1.4700000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 2.1653733753999364E-005 # shield thickness + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.10000000000000001 1.0000000000000001E-009 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor x y positions + 5.0000000000000001E-003 0.0000000000000000 + -5.0000000000000001E-003 0.0000000000000000 + -5.0000000000000001E-003 0.0000000000000000 +is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc + F 0 2 2 1 3 + F 0 1 1 1 3 + T 1 2 3 2 3 + # Conductor labels + Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire + Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire + Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield diff --git a/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_Coax.bundle_spec b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_Coax.bundle_spec new file mode 100644 index 0000000..39c4169 --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_Coax.bundle_spec @@ -0,0 +1,11 @@ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +2 #Number of cables in bundle, cable list follows +bare_wire +0.005 0.0 0 +coaxial_cable_01 +-0.005 0.0 0 +no_ground_plane +no_laplace diff --git a/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_twinax.bundle b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_twinax.bundle new file mode 100644 index 0000000..bf8d8db --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_twinax.bundle @@ -0,0 +1,181 @@ +v4.0.0 +ZT_FD_twinax + 1 ! number of cables not including ground plane + 1 ! number of cables, cable name and x y coordinates follow... +twinax_cable + 0.0000000000000000 0.0000000000000000 0.0000000000000000 x y coordinates and angle of cable +no_ground_plane + 3 # total number of conductors + 1 # total number of external conductors + 2 # dimension of the matrix system characterising the MTL propagation + 1 # number of domains + Domain number 1 + 3 number of conductors in this domain + terminal_conductor_list + 3 ! number of elements + 1 + 2 + 3 + Per-Unit-length Inductance Matrix, [L] + 2 Dimension of [L] + 4.02980604E-07 1.50754360E-07 + 1.50754360E-07 4.02980604E-07 + Per-Unit-length Capacitance Matrix, [C] + 2 Dimension of [C] + 7.22325649E-11 -2.70220800E-11 + -2.70220800E-11 7.22325649E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.0298060410845298E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.5075436047527605E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.5075436047527605E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.0298060410845298E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 7.2232564935120276E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.7022080023862092E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.7022080023862092E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 7.2232564935120276E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Global current domain transformation matrix, [MI] + 2 Dimension of [MI] + 1.00000000E+00 0.00000000E+00 + 0.00000000E+00 1.00000000E+00 + # Global voltage domain transformation matrix, [MV] + 2 Dimension of [MV] + 1.00000000E+00 0.00000000E+00 + 0.00000000E+00 1.00000000E+00 + # Global domain based inductance matrix, [L] + 2 Dimension of [L] + 4.02980604E-07 1.50754360E-07 + 1.50754360E-07 4.02980604E-07 + # Global domain based capacitance matrix, [C] + 2 Dimension of [C] + 7.22325649E-11 -2.70220800E-11 + -2.70220800E-11 7.22325649E-11 + Global domain based Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.0298060410845298E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.5075436047527605E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.5075436047527605E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.0298060410845298E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Global domain based Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 7.2232564935120276E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.7022080023862092E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.7022080023862092E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 7.2232564935120276E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor impedance models + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 1.5915494309189530E-005 # shield thickness + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.10000000000000001 1.0000000000000001E-009 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # conductor x y positions + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 + 0.0000000000000000 0.0000000000000000 +is_shield tc_to_in_domain tc_to_out_domain tc_to_gdc tc_to_ldc tc_to_ref_tc + F 0 1 1 1 3 + F 0 1 2 2 3 + F 0 2 3 1 3 + # Conductor labels + Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 + Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 + Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield diff --git a/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_twinax.bundle_spec b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_twinax.bundle_spec new file mode 100644 index 0000000..5e0fdcd --- /dev/null +++ b/MOD_WEB_EXAMPLES/BUNDLE/ZT_FD_twinax.bundle_spec @@ -0,0 +1,9 @@ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +#MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +1 #Number of cables in bundle, cable list follows +twinax_cable +0.0 0.0 0 +no_ground_plane +no_laplace diff --git a/MOD_WEB_EXAMPLES/CABLE/bare_wire.cable b/MOD_WEB_EXAMPLES/CABLE/bare_wire.cable new file mode 100644 index 0000000..22bb37e --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/bare_wire.cable @@ -0,0 +1,54 @@ +v4.0.0 +cylindrical + 1 # cable type number + 1 # Total Number of conductors + 1 # Number of external conductors + 1 # Total number of domains (including external domain) + 0 # Number of internal conductors + 0 # Number of internal domains + 3 # Number of cable parameters + 1.0000000000000000E-004 + 1.0000000000000000E-004 + 0.0000000000000000 + 1 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 1.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 1.0000000000000000E-004 # conductor radius + 0.0000000000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + External to domain conductor current transformation matrix, MI + 2 Dimension of MI + 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 2 Dimension of MV + 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 1.00000000E+00 + # Local reference conductor for internal domains + 0 + # number of conductors in each domain + 2 + # External conductor information and dielectric model + 1 conductor type + 1.0000000000000000E-004 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 1.0000000000000000E-004 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 1.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor labels + Cable name: bare_wire. type: cylindrical. conductor 1 : wire diff --git a/MOD_WEB_EXAMPLES/CABLE/bare_wire.cable_spec b/MOD_WEB_EXAMPLES/CABLE/bare_wire.cable_spec new file mode 100644 index 0000000..7e608ef --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/bare_wire.cable_spec @@ -0,0 +1,15 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Cylindrical +1 #number of conductors +3 #number of parameters +0.1e-3 # parameter 1: conductor radius +0.1e-3 # parameter 2: dielectric radius +0.0 # parameter 3: conductivity +1 # number of frequency dependent parameters +# Dielectric relative permittivity model follows +1.0 # w normalisation constant +0 # a order, a coefficients follow below +1.00 +0 # b order, b coefficients follow below +1.0 diff --git a/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_01.cable b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_01.cable new file mode 100644 index 0000000..d4628a3 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_01.cable @@ -0,0 +1,104 @@ +v4.0.0 +coax + 4 # cable type number + 2 # Total Number of conductors + 1 # Number of external conductors + 2 # Total number of domains (including external domain) + 1 # Number of internal conductors + 1 # Number of internal domains + 6 # Number of cable parameters + 4.2000000000000002E-004 + 1.4700000000000000E-003 + 2.5000000000000001E-003 + 50000000.000000000 + 0.0000000000000000 + 50000000.000000000 + 2 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 10000000.000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.6000000000000001 2.3999999999999999 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Dielectric filter number 2 + 10000000.000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.3999999999999999 2.2000000000000002 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 4.2000000000000002E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 1.4700000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 2.1653733753999364E-005 # shield thickness + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.10000000000000001 1.0000000000000001E-009 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + External to domain conductor current transformation matrix, MI + 3 Dimension of MI + 1.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 3 Dimension of MV + 1.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 + Domain number 1 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 2.50552594E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 1.06578826E-10 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.5055259369907356E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 10000000.000000000 # w normalisation constant + 2 # a order, a coefficients follow below: + 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Local reference conductor for internal domains + 2 + 0 + # number of conductors in each domain + 2 + 2 + # External conductor information and dielectric model + 1 conductor type + 1.4700000000000000E-003 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 2.5000000000000001E-003 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 10000000.000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.3999999999999999 2.2000000000000002 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Conductor labels + Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire + Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield diff --git a/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_01.cable_spec b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_01.cable_spec new file mode 100644 index 0000000..dbbaa5c --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_01.cable_spec @@ -0,0 +1,31 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Coax +2 #number of conductors +6 #number of parameters +4.2e-4 # parameter 1: inner conductor radius (m) +1.47e-3 # parameter 2: shield radius +2.5e-3 # parameter 3: outer insulation radius (m) +5.0e7 # parameter 4: inner conductor electric conductivity +0.0 # parameter 5: shield conductor thickness +5.0e7 # parameter 6: shield electric conductivity +2 # number of frequency dependent parameters +# Inner dielectric relative permittivity +1e7 # w normalisation constant +1 # a order, a coefficients follow below +2.6 2.4 +1 # b order, b coefficients follow below +1.0 1.0 +# Outer dielectric relative permittivity +1e7 # w normalisation constant +1 # a order, a coefficients follow below +2.4 2.2 +1 # b order, b coefficients follow below +1.0 1.0 +1 # number of frequency dependent transfer impedance models +# Transfer impedance model +1 # angular frequency normalisation +1 # order of numerator model +0.1 1e-9 # list of numerator coefficients a0 a1 a2... +0 # order of denominator model +1 # list of denominator coefficients b0 b1 b2... diff --git a/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_02.cable b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_02.cable new file mode 100644 index 0000000..22b4dd7 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_02.cable @@ -0,0 +1,104 @@ +v4.0.0 +coax + 4 # cable type number + 2 # Total Number of conductors + 1 # Number of external conductors + 2 # Total number of domains (including external domain) + 1 # Number of internal conductors + 1 # Number of internal domains + 6 # Number of cable parameters + 4.2000000000000002E-004 + 1.4700000000000000E-003 + 2.5000000000000001E-003 + 50000000.000000000 + 0.0000000000000000 + 50000000.000000000 + 2 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 10000000.000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.6000000000000001 2.3999999999999999 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Dielectric filter number 2 + 10000000.000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.3999999999999999 2.2000000000000002 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 4.2000000000000002E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 1.4700000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 7.2179112513331222E-006 # shield thickness + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.29999999999999999 1.0000000000000000E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + External to domain conductor current transformation matrix, MI + 3 Dimension of MI + 1.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 3 Dimension of MV + 1.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 + Domain number 1 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 2.50552594E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 1.06578826E-10 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.5055259369907356E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 10000000.000000000 # w normalisation constant + 2 # a order, a coefficients follow below: + 0.0000000000000000 1.1546039508205030E-003 1.0657882622958489E-003 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Local reference conductor for internal domains + 2 + 0 + # number of conductors in each domain + 2 + 2 + # External conductor information and dielectric model + 1 conductor type + 1.4700000000000000E-003 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 2.5000000000000001E-003 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 10000000.000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.3999999999999999 2.2000000000000002 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Conductor labels + Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire + Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield diff --git a/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_02.cable_spec b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_02.cable_spec new file mode 100644 index 0000000..a1c468b --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/coaxial_cable_02.cable_spec @@ -0,0 +1,31 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Coax +2 #number of conductors +6 #number of parameters +4.2e-4 # parameter 1: inner conductor radius (m) +1.47e-3 # parameter 2: shield radius +2.5e-3 # parameter 3: outer insulation radius (m) +5e7 # parameter 4: inner conductor electric conductivity +0.0 # parameter 5: shield conductor thickness +5e7 # parameter 6: shield electric conductivity +2 # number of frequency dependent parameters +# Inner dielectric relative permittivity +1e7 # w normalisation constant +1 # a order, a coefficients follow below +2.6 2.4 +1 # b order, b coefficients follow below +1.0 1.0 +# Outer dielectric relative permittivity +1e7 # w normalisation constant +1 # a order, a coefficients follow below +2.4 2.2 +1 # b order, b coefficients follow below +1.0 1.0 +1 # number of frequency dependent transfer impedance models +# Transfer impedance model +1 # angular frequency normalisation +1 # order of numerator model +0.3 1e-8 # list of numerator coefficients a0 a1 a2... +0 # order of denominator model +1 # list of denominator coefficients b0 b1 b2... diff --git a/MOD_WEB_EXAMPLES/CABLE/single_wire.cable b/MOD_WEB_EXAMPLES/CABLE/single_wire.cable new file mode 100644 index 0000000..e7dc5ba --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/single_wire.cable @@ -0,0 +1,54 @@ +v4.0.0 +cylindrical + 1 # cable type number + 1 # Total Number of conductors + 1 # Number of external conductors + 1 # Total number of domains (including external domain) + 0 # Number of internal conductors + 0 # Number of internal domains + 3 # Number of cable parameters + 1.9050000000000000E-004 + 5.0000000000000001E-004 + 50000000.000000000 + 1 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 100000000.00000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.6000000000000001 2.2500000000000000 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 1.9050000000000000E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + External to domain conductor current transformation matrix, MI + 2 Dimension of MI + 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 2 Dimension of MV + 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 1.00000000E+00 + # Local reference conductor for internal domains + 0 + # number of conductors in each domain + 2 + # External conductor information and dielectric model + 1 conductor type + 1.9050000000000000E-004 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 5.0000000000000001E-004 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 100000000.00000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 2.6000000000000001 2.2500000000000000 + 1 # b order, b coefficients follow below: + 1.0000000000000000 1.0000000000000000 + # Conductor labels + Cable name: single_wire. type: cylindrical. conductor 1 : wire diff --git a/MOD_WEB_EXAMPLES/CABLE/single_wire.cable_spec b/MOD_WEB_EXAMPLES/CABLE/single_wire.cable_spec new file mode 100644 index 0000000..48d509f --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/single_wire.cable_spec @@ -0,0 +1,15 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Cylindrical +1 #number of conductors +3 #number of parameters +1.905e-4 # parameter 1: conductor radius +0.5e-3 # parameter 2: dielectric radius +5e7 # parameter 3: conductivity +1 # number of frequency dependent parameters +# Dielectric relative permittivity model follows +1e8 # w normalisation constant +1 # a order, a coefficients follow below +2.60 2.25 +1 # b order, b coefficients follow below +1.0 1.0 diff --git a/MOD_WEB_EXAMPLES/CABLE/spacewire.cable b/MOD_WEB_EXAMPLES/CABLE/spacewire.cable new file mode 100644 index 0000000..255c921 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/spacewire.cable @@ -0,0 +1,631 @@ +v4.0.0 +spacewire + 6 # cable type number + 13 # Total Number of conductors + 1 # Number of external conductors + 10 # Total number of domains (including external domain) + 12 # Number of internal conductors + 9 # Number of internal domains + 13 # Number of cable parameters + 2.5000000000000001E-004 + 4.4999999999999999E-004 + 1.0000000000000000E-003 + 2.0000000000000000E-003 + 6.2500000000000001E-005 + 2.2000000000000001E-003 + 4.0000000000000001E-003 + 8.0000000000000002E-003 + 5.8594000000000002E-005 + 8.9999999999999993E-003 + 50000000.000000000 + 50000000.000000000 + 50000000.000000000 + 3 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 2.2500000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Dielectric filter number 2 + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 4.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Dielectric filter number 3 + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 2.2500000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 0.50000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 6.2500000000000001E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 + 5 # b order, b coefficients follow below: + 1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 + 4 # Conductor impedance model type + 8.0000000000000002E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 5.8594000000000002E-005 # shield thickness + 628318530.71795857 # w normalisation constant + 6 # a order, a coefficients follow below: + 6.7910018908980910E-003 6.3516651586671768 131.85223712596317 714.73088207712362 1550.1604988129416 1509.1499548754166 617.70419490065785 + 5 # b order, b coefficients follow below: + 1.0000000000000000 20.715352684308218 112.30217945904732 243.56691527043952 237.12345747204483 97.056063856769896 + External to domain conductor current transformation matrix, MI + 14 Dimension of MI + 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 -5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 14 Dimension of MV + 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 5.00000000E-01 5.00000000E-01 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 0.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 + Domain number 1 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 4.82554527E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 2 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 2.68677221E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 3 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 4.82554527E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 4 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 2.68677221E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 5 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 4.82554527E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 6 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 2.68677221E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 7 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 4.82554527E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 3.38180465E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8255452695104674E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.3818046452081898E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 8 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 2.68677221E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 4.82242002E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.6867722148577337E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.8224200154967981E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Domain number 9 + 5 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 4 Dimension of L + 1.84316340E-07 5.39918049E-08 3.13072143E-08 5.39881438E-08 + 5.39918049E-08 1.84319509E-07 5.39831349E-08 3.13087805E-08 + 3.13072143E-08 5.39831349E-08 1.84332861E-07 5.39800105E-08 + 5.39881438E-08 3.13087805E-08 5.39800105E-08 1.84326252E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 4 Dimension of C + 8.10461294E-11 -2.09376538E-11 -1.93945500E-12 -2.09339121E-11 + -2.09376538E-11 8.10428561E-11 -2.09295921E-11 -1.94046442E-12 + -1.93945500E-12 -2.09295921E-11 8.10305676E-11 -2.09263826E-11 + -2.09339121E-11 -1.94046442E-12 -2.09263826E-11 8.10359177E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 4 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8431633950127736E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3991804942125718E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1307214294412737E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3988143811142774E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3991804942125718E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8431950926864761E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3983134865942856E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1308780454336411E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1307214294412737E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3983134865942856E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8433286095430542E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3980010475558271E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3988143811142774E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 3.1308780454336411E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3980010475558271E-008 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.8432625193110204E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 4 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1046129434812118E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0937653783662812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9394550041484633E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0933912129944816E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0937653783662812E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1042856062401348E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0929592068643566E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9404644230052613E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9394550041484633E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0929592068643566E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1030567551953170E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 3 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0926382619037890E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0933912129944816E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -1.9404644230052613E-012 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 3 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.0926382619037890E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 4 4 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 8.1035917699675775E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Local reference conductor for internal domains + 2 + 9 + 3 + 10 + 4 + 11 + 5 + 12 + 13 + 13 + 13 + 13 + 0 + # number of conductors in each domain + 2 + 2 + 2 + 2 + 2 + 2 + 2 + 2 + 5 + 2 + # External conductor information and dielectric model + 1 conductor type + 8.0000000000000002E-003 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 8.9999999999999993E-003 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 2.2500000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor labels + Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 + Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 + Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 + Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 + Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 + Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 + Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 + Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 + Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 + Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 + Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 + Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 + Cable name: spacewire. type: spacewire. conductor 13: Outer Shield diff --git a/MOD_WEB_EXAMPLES/CABLE/spacewire.cable_spec b/MOD_WEB_EXAMPLES/CABLE/spacewire.cable_spec new file mode 100644 index 0000000..12a42ce --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/spacewire.cable_spec @@ -0,0 +1,51 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Spacewire +13 #number of conductors +13 #number of parameters +2.5e-4 # parameter 1: inner conductor radius (m) +4.5e-4 # parameter 2: inner dielectric radius (m) +1.0e-3 # parameter 3: inner conductor separation (m) +2.0e-3 # parameter 4: inner shield radius (m) +6.25e-5 # parameter 5: inner shield thickness (m) +2.2e-3 # parameter 6: inner shield jacket radius (m) +4.0e-3 # parameter 7: shielded twisted pair radius (m) +8.0e-3 # parameter 8: outer shield radius (m) +5.8594e-5 # parameter 9: outer shield thickness (m) +9.0e-3 # parameter 10: outer dielectric radius (m) +5e7 # parameter 11: inner conductor electric conductivity (m) +5e7 # parameter 12: inner shield electric conductivity (m) +5e7 # parameter 13: inner shield electric conductivity (m) +3 # number of frequency dependent parameters +# Inner dielectric relative permittivity +1e7 # w normalisation constant +0 # a order, a coefficients follow below +2.25 +0 # b order, b coefficients follow below +1.0 +# Inner shield dielectric relative permittivity +1e7 # w normalisation constant +0 # a order, a coefficients follow below +4.0 +0 # b order, b coefficients follow below +1.0 +# Outer dielectric relative permittivity +1e7 # w normalisation constant +0 # a order, a coefficients follow below +2.25 +0 # b order, b coefficients follow below +1.0 +2 # number of frequency dependent transfer impedance models +# Inner shield Transfer impedance mode +628318530.71795857 # angular frequency normalisation +6 # order of numerator model +2.5468494337902981E-002 8.2338738578784980 195.63548903976618 1209.1421442346702 3006.6530418447878 3357.6215437592941 1630.6481239088137 # list of numerator coefficients a0 a1 a2... +5 # order of denominator model +1.0000000000000000 23.599449123864371 145.90222072648291 362.78999275303835 405.14016972907552 196.75864271145394 # list of denominator coefficients b0 b1 b2... +# Outer shield Transfer impedance mode +628318530.71795857 # angular frequency normalisation +6 # order of numerator model +6.7910018908980910E-003 6.3516651586671768 131.85223712596317 714.73088207712362 1550.1604988129416 1509.1499548754166 617.70419490065785 # list of numerator coefficients a0 a1 a2... +5 # order of denominator model +1.0000000000000000 20.715352684308218 112.30217945904732 243.56691527043952 237.12345747204483 97.056063856769896 # list of denominator coefficients b0 b1 b2... +use_laplace diff --git a/MOD_WEB_EXAMPLES/CABLE/twinax_cable.cable b/MOD_WEB_EXAMPLES/CABLE/twinax_cable.cable new file mode 100644 index 0000000..f0964a3 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/twinax_cable.cable @@ -0,0 +1,152 @@ +v4.0.0 +twinax + 7 # cable type number + 3 # Total Number of conductors + 1 # Number of external conductors + 2 # Total number of domains (including external domain) + 2 # Number of internal conductors + 1 # Number of internal domains + 8 # Number of cable parameters + 2.5000000000000001E-004 + 4.4999999999999999E-004 + 1.0000000000000000E-003 + 2.0000000000000000E-003 + 0.0000000000000000 + 3.0000000000000001E-003 + 50000000.000000000 + 50000000.000000000 + 2 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 2.2500000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Dielectric filter number 2 + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 2.2500000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 4 # Conductor impedance model type + 2.0000000000000000E-003 # conductor radius + 50000000.000000000 # conductivity + 1.0000000000000000 # Resistance_multiplication_factor + 1.5915494309189530E-005 # shield thickness + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.10000000000000001 1.0000000000000001E-009 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + External to domain conductor current transformation matrix, MI + 4 Dimension of MI + 1.00000000E+00 0.00000000E+00 0.00000000E+00 0.00000000E+00 + 0.00000000E+00 1.00000000E+00 0.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 4 Dimension of MV + 1.00000000E+00 0.00000000E+00 -1.00000000E+00 -0.00000000E+00 + 0.00000000E+00 1.00000000E+00 -1.00000000E+00 0.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 -1.00000000E+00 + 0.00000000E+00 0.00000000E+00 0.00000000E+00 1.00000000E+00 + Domain number 1 + 3 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 2 Dimension of L + 4.02980604E-07 1.50754360E-07 + 1.50754360E-07 4.02980604E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 2 Dimension of C + 7.22325649E-11 -2.70220800E-11 + -2.70220800E-11 7.22325649E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.0298060410845298E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.5075436047527605E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 1.5075436047527605E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 4.0298060410845298E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 2 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 7.2232564935120276E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 1 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.7022080023862092E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + -0.0000000000000000 -2.7022080023862092E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 +Element: 2 2 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 7.2232564935120276E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Local reference conductor for internal domains + 3 + 3 + 0 + # number of conductors in each domain + 3 + 2 + # External conductor information and dielectric model + 1 conductor type + 2.0000000000000000E-003 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 3.0000000000000001E-003 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 10000000.000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 2.2500000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor labels + Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 + Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 + Cable name: twinax_cable. type: twinax. conductor 3 : Shield diff --git a/MOD_WEB_EXAMPLES/CABLE/twinax_cable.cable_spec b/MOD_WEB_EXAMPLES/CABLE/twinax_cable.cable_spec new file mode 100644 index 0000000..04d4711 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/twinax_cable.cable_spec @@ -0,0 +1,34 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Twinax +3 #number of conductors +8 #number of parameters +0.25e-3 # parameter 1: inner conductor radius (m) +0.45e-3 # parameter 2: inner dielectric radius (m) +1.0e-3 # parameter 3: inner conductor separation (m) +2.0e-3 # parameter 4: shield radius (m) +0.0 # parameter 5: shield thickness (m) +3.0e-3 # parameter 6: outer dielectric radius (m) +5e7 # parameter 7: inner conductor electric conductivity (m) +5e7 # parameter 8: shield electric conductivity (m) +2 #number of frequency dependent parameters +# Inner dielectric relative permittivity +1e7 # w normalisation constant +0 # a order, a coefficents follow below +2.25 +0 # b order, b coefficents follow below +1.0 +# Outer dielectric relative permittivity +1e7 # w normalisation constant +0 # a order, a coefficents follow below +2.25 +0 # b order, b coefficents follow below +1.0 +1 # number of frequency dependent transfer impedance models +# Transfer impedance model +1 # angular frequency normalisation +1 # order of numerator model +0.1 1e-9 # list of numerator coefficients a0 a1 a2... +0 # order of denominator model +1 # list of denominator coefficients b0 b1 b2... +no_laplace diff --git a/MOD_WEB_EXAMPLES/CABLE/twisted_pair.cable b/MOD_WEB_EXAMPLES/CABLE/twisted_pair.cable new file mode 100644 index 0000000..7143b35 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/twisted_pair.cable @@ -0,0 +1,90 @@ +v4.0.0 +twisted_pair + 2 # cable type number + 2 # Total Number of conductors + 1 # Number of external conductors + 2 # Total number of domains (including external domain) + 1 # Number of internal conductors + 1 # Number of internal domains + 4 # Number of cable parameters + 2.5000000000000001E-004 + 1.0000000000000000E-003 + 4.4999999999999999E-004 + 0.0000000000000000 + 1 # number of frequency dependent dielectric models + # Dielectric filter number 1 + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 1.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor impedance models + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 0.0000000000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + 1 # Conductor impedance model type + 2.5000000000000001E-004 # conductor radius + 0.0000000000000000 # conductivity + 1.5000000000000000 # Resistance_multiplication_factor + External to domain conductor current transformation matrix, MI + 3 Dimension of MI + 5.00000000E-01 -5.00000000E-01 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 0.00000000E+00 + 1.00000000E+00 1.00000000E+00 1.00000000E+00 + External to domain conductor voltage transformation matrix, MV + 3 Dimension of MV + 1.00000000E+00 -1.00000000E+00 0.00000000E+00 + 5.00000000E-01 5.00000000E-01 -1.00000000E+00 + 0.00000000E+00 0.00000000E+00 1.00000000E+00 + Domain number 1 + 2 # number of conductors + High frequency Per-Unit-length Inductance Matrix, L + 1 Dimension of L + 5.30708040E-07 + High frequency Per-Unit-length Capacitance Matrix, C + 1 Dimension of C + 2.09653891E-11 + Per-Unit-length Impedance Matrix, Z + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 5.3070804032283549E-007 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + Per-Unit-length Admittance Matrix, Y + Matrix of Laplace domain filters + 1 # dimension of Sfilter matrix +Element: 1 1 + 1.0000000000000000 # w normalisation constant + 1 # a order, a coefficients follow below: + 0.0000000000000000 2.0965389093676046E-011 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Local reference conductor for internal domains + 2 + 0 + # number of conductors in each domain + 2 + 2 + # External conductor information and dielectric model + 1 conductor type + 3.7500000000000001E-004 conductor_radius + 0.0000000000000000 conductor_width + 0.0000000000000000 conductor_width2 + 0.0000000000000000 conductor_height + 0.0000000000000000 0.0000000000000000 conductor_ox, conductor_oy + 5.7499999999999999E-004 dielectric_radius + 0.0000000000000000 dielectric_width + 0.0000000000000000 dielectric_height + 0.0000000000000000 0.0000000000000000 dielectric_ox, dielectric_oy + 1.0000000000000000 # w normalisation constant + 0 # a order, a coefficients follow below: + 1.0000000000000000 + 0 # b order, b coefficients follow below: + 1.0000000000000000 + # Conductor labels + Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 + Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 diff --git a/MOD_WEB_EXAMPLES/CABLE/twisted_pair.cable_spec b/MOD_WEB_EXAMPLES/CABLE/twisted_pair.cable_spec new file mode 100644 index 0000000..f1e6b75 --- /dev/null +++ b/MOD_WEB_EXAMPLES/CABLE/twisted_pair.cable_spec @@ -0,0 +1,17 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +Twisted_pair +2 #number of conductors +4 #number of parameters +0.25e-3 # parameter 1: conductor radius (m) +1.0e-3 # parameter 2: conductor separation (m) +4.5e-4 # parameter 3: dielectric radius (m) +0.0 # parameter 4: inner conductor electric conductivity (m) +1 # number of frequency dependent parameters + # Dielectric relative permittivity model follows +1.0 # w normalisation constant +0 # a order, a coefficients follow below +1.00 +0 # b order, b coefficients follow below +1.0 +use_laplace diff --git a/MOD_WEB_EXAMPLES/MOD_WEB_EXAMPLES.zip b/MOD_WEB_EXAMPLES/MOD_WEB_EXAMPLES.zip new file mode 100644 index 0000000..6a4fbb5 Binary files /dev/null and b/MOD_WEB_EXAMPLES/MOD_WEB_EXAMPLES.zip differ diff --git a/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField.spice_model_spec b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField.spice_model_spec new file mode 100644 index 0000000..fae293f --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField.spice_model_spec @@ -0,0 +1,19 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +# MOD_bundle_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +# MOD_spice_bundle_lib_dir +../MOD_WEB_EXAMPLES/SPICE/ +# spice_symbol_dir +../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ +# Specification for spice model of Coax_Gnd_EField +Coax_Gnd_EField +# cable bundle length (m) +1.22 +# Incident field specification +1.0 amplitude (V/m) +60.0 202.0 ktheta kphi (degrees) +1.0 0.5 Etheta Ephi (degrees) +# Transfer Impedance Model +0 # number of transfer impedances to include in the model +No_validation_test \ No newline at end of file diff --git a/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_LTspice.lib b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_LTspice.lib new file mode 100644 index 0000000..76f9757 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_LTspice.lib @@ -0,0 +1,299 @@ +* LTspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 4 Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire +* node: 5 Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield +* node: 6 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* End 2 nodes: +* +* node: 7 Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire +* node: 8 Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield +* node: 9 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* Incident field function nodes: +* +* 2 3 +* +.subckt Coax_Gnd_EField ++ 4 5 6 ++ 7 8 9 ++ 2 3 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 4 10 2.201463E-02 +Rdc_c2_e1 5 11 1.830000E-01 +Rdc_c3_e1 6 1 6.100000E-09 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 7 12 2.201463E-02 +Rdc_c2_e2 8 13 1.830000E-01 +Rdc_c3_e2 9 1 6.100000E-09 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 10 16 +Vmeas_domain_decomp_c2_e1 11 18 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 16 17 14 1 1.000000E+00 +E_domain_decomp_c1_dc2_e1 17 1 15 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 18 19 14 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e1 19 1 15 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 14 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc1_e1 1 14 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 15 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 15 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 12 22 +Vmeas_domain_decomp_c2_e2 13 24 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 22 23 20 1 1.000000E+00 +E_domain_decomp_c1_dc2_e2 23 1 21 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 24 25 20 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e2 25 1 21 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 20 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc1_e2 1 20 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 21 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 21 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 14 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 26 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 20 29 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 29 1 28 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 28 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 26 30 4.848574E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 28 31 4.848574E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 30 1 32 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 31 1 33 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 33 1 34 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.220000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 32 1 35 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.220000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 33 1 4.848574E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 32 1 4.848574E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 34 36 26 1 2.000000E+00 +E_m_pz_d1_m1_e2 36 1 30 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 35 37 28 1 2.000000E+00 +E_m_mz_d1_m1_e2 37 1 31 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 15 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 38 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 21 41 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 41 1 40 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 40 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 38 44 1.980799E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 40 45 1.980799E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 44 42 46 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 45 43 47 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 47 1 48 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 6.607234E-07 C= 1.683988E-11 LEN= 1.220000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 46 1 49 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 6.607234E-07 C= 1.683988E-11 LEN= 1.220000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 47 1 1.980799E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 46 1 1.980799E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 48 50 38 1 2.000000E+00 +E_m_pz_d2_m1_e2 50 1 44 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 49 51 40 1 2.000000E+00 +E_m_mz_d2_m1_e2 51 1 45 1 -1.000000E+00 +* +* START OF INCIDENT FIELD EXCITATION MODELS +* +* +* Incident field delay lines, Tz delay +* +O_T_Tz_Einc 53 1 54 1 LTRA_T_Tz_Einc +.MODEL LTRA_T_Tz_Einc LTRA( R=0.0 L= 8.339102E-08 C= 3.335641E-11 LEN= 1.220000E+00 ) +* +* Matched impedance: Tz delay +* +RZC_Tz_Einc 54 1 0.500000E+02 +* +* Delay line controlled sources Tz delay +* +E1_Tz_Einc 53 1 2 3 0.100000E+01 +* +* Delay line Tz+T_victim(v_mode) +* +O_T_TzPTv_EINC_vm_1 55 1 56 1 LTRA_T_TzPTv_EINC_vm_1 +.MODEL LTRA_T_TzPTv_EINC_vm_1 LTRA( R=0.0 L= 2.501731E-07 C= 1.000692E-10 LEN= 1.220000E+00 ) +* +* Matched impedance: Tz+T_victim(v_mode) delay +* +RZC_TzPTv_EINC_vm_1 56 1 0.500000E+02 +* +* Incident field delay line controlled source: Tz+T_victim(v_mode) delay +* +E1_TzPTv_EINC_vm_1 55 1 2 3 0.100000E+01 +* +* Incident field delay line T_victim(v_mode) +* +O_T_Tv_EINC_vm_1 57 1 58 1 LTRA_T_Tv_EINC_vm_1 +.MODEL LTRA_T_Tv_EINC_vm_1 LTRA( R=0.0 L= 1.667820E-07 C= 6.671282E-11 LEN= 1.220000E+00 ) +* +* Matched impedance T_victim(v_mode) delay +* +RZC_Tv_EINC_vm_1 58 1 0.500000E+02 +* +* Controlled source for T_victim(v_mode) delay +* +E1_Tv_EINC_vm_1 57 1 2 3 0.100000E+01 +* +* Circuit to combine incident field excitation terms +* +E_zt_dsum_s_EINC_vm_1_E1 59 1 2 3 0.299883E-01 +E_zt_dsum_s_EINC_vm_1_E2 60 59 56 1 -0.299883E-01 +E_zt_dsum_l_EINC_vm_1_E1 61 1 58 1 -0.318364E-02 +E_zt_dsum_l_EINC_vm_1_E2 62 61 54 1 0.318364E-02 +* +* Large resistance to complete the circuit for the series voltage sources +* +R_Einc_dsum_l_EINC_vm_1 62 1 0.100000E+01 +R_Einc_dsum_s_EINC_vm_1 60 1 0.100000E+01 +* +* Incident field excitation sources, end 1 +* +E_Einc_s_EINC_vm_1 42 1 60 1 1.000000E+00 +* +* Incident field excitation sources, end 2 +* +E_Einc_l_EINC_vm_1 43 1 62 1 1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_Ngspice.lib b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_Ngspice.lib new file mode 100644 index 0000000..b617f52 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_Ngspice.lib @@ -0,0 +1,299 @@ +* Ngspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 4 Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire +* node: 5 Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield +* node: 6 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* End 2 nodes: +* +* node: 7 Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire +* node: 8 Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield +* node: 9 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* Incident field function nodes: +* +* 2 3 +* +.subckt Coax_Gnd_EField ++ 4 5 6 ++ 7 8 9 ++ 2 3 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 4 10 2.201463E-02 +Rdc_c2_e1 5 11 1.830000E-01 +Rdc_c3_e1 6 1 6.100000E-09 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 7 12 2.201463E-02 +Rdc_c2_e2 8 13 1.830000E-01 +Rdc_c3_e2 9 1 6.100000E-09 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 10 16 +Vmeas_domain_decomp_c2_e1 11 18 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 16 17 14 1 1.000000E+00 +E_domain_decomp_c1_dc2_e1 17 1 15 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 18 19 14 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e1 19 1 15 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 14 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc1_e1 1 14 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 15 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 15 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 12 22 +Vmeas_domain_decomp_c2_e2 13 24 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 22 23 20 1 1.000000E+00 +E_domain_decomp_c1_dc2_e2 23 1 21 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 24 25 20 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e2 25 1 21 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 20 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc1_e2 1 20 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 21 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 21 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 14 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 26 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 20 29 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 29 1 28 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 28 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 26 30 4.848574E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 28 31 4.848574E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 30 1 32 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 31 1 33 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 33 1 34 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.220000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 32 1 35 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.220000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 33 1 4.848574E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 32 1 4.848574E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 34 36 26 1 2.000000E+00 +E_m_pz_d1_m1_e2 36 1 30 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 35 37 28 1 2.000000E+00 +E_m_mz_d1_m1_e2 37 1 31 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 15 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 38 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 21 41 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 41 1 40 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 40 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 38 44 1.980799E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 40 45 1.980799E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 44 42 46 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 45 43 47 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 47 1 48 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 6.607234E-07 C= 1.683988E-11 LEN= 1.220000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 46 1 49 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 6.607234E-07 C= 1.683988E-11 LEN= 1.220000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 47 1 1.980799E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 46 1 1.980799E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 48 50 38 1 2.000000E+00 +E_m_pz_d2_m1_e2 50 1 44 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 49 51 40 1 2.000000E+00 +E_m_mz_d2_m1_e2 51 1 45 1 -1.000000E+00 +* +* START OF INCIDENT FIELD EXCITATION MODELS +* +* +* Incident field delay lines, Tz delay +* +O_T_Tz_Einc 53 1 54 1 LTRA_T_Tz_Einc +.MODEL LTRA_T_Tz_Einc LTRA( R=0.0 L= 8.339102E-08 C= 3.335641E-11 LEN= 1.220000E+00 ) +* +* Matched impedance: Tz delay +* +RZC_Tz_Einc 54 1 0.500000E+02 +* +* Delay line controlled sources Tz delay +* +E1_Tz_Einc 53 1 2 3 0.100000E+01 +* +* Delay line Tz+T_victim(v_mode) +* +O_T_TzPTv_EINC_vm_1 55 1 56 1 LTRA_T_TzPTv_EINC_vm_1 +.MODEL LTRA_T_TzPTv_EINC_vm_1 LTRA( R=0.0 L= 2.501731E-07 C= 1.000692E-10 LEN= 1.220000E+00 ) +* +* Matched impedance: Tz+T_victim(v_mode) delay +* +RZC_TzPTv_EINC_vm_1 56 1 0.500000E+02 +* +* Incident field delay line controlled source: Tz+T_victim(v_mode) delay +* +E1_TzPTv_EINC_vm_1 55 1 2 3 0.100000E+01 +* +* Incident field delay line T_victim(v_mode) +* +O_T_Tv_EINC_vm_1 57 1 58 1 LTRA_T_Tv_EINC_vm_1 +.MODEL LTRA_T_Tv_EINC_vm_1 LTRA( R=0.0 L= 1.667820E-07 C= 6.671282E-11 LEN= 1.220000E+00 ) +* +* Matched impedance T_victim(v_mode) delay +* +RZC_Tv_EINC_vm_1 58 1 0.500000E+02 +* +* Controlled source for T_victim(v_mode) delay +* +E1_Tv_EINC_vm_1 57 1 2 3 0.100000E+01 +* +* Circuit to combine incident field excitation terms +* +E_zt_dsum_s_EINC_vm_1_E1 59 1 2 3 0.299883E-01 +E_zt_dsum_s_EINC_vm_1_E2 60 59 56 1 -0.299883E-01 +E_zt_dsum_l_EINC_vm_1_E1 61 1 58 1 -0.318364E-02 +E_zt_dsum_l_EINC_vm_1_E2 62 61 54 1 0.318364E-02 +* +* Large resistance to complete the circuit for the series voltage sources +* +R_Einc_dsum_l_EINC_vm_1 62 1 0.100000E+01 +R_Einc_dsum_s_EINC_vm_1 60 1 0.100000E+01 +* +* Incident field excitation sources, end 1 +* +E_Einc_s_EINC_vm_1 42 1 60 1 1.000000E+00 +* +* Incident field excitation sources, end 2 +* +E_Einc_l_EINC_vm_1 43 1 62 1 1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_PSpice.lib b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_PSpice.lib new file mode 100644 index 0000000..e220b3c --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Coax_Gnd_EField_PSpice.lib @@ -0,0 +1,299 @@ +* Pspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 4 Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire +* node: 5 Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield +* node: 6 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* End 2 nodes: +* +* node: 7 Conductor number 1. Cable name: coaxial_cable_02. type: coax. conductor 1 : Inner wire +* node: 8 Conductor number 2. Cable name: coaxial_cable_02. type: coax. conductor 2 : Shield +* node: 9 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* Incident field function nodes: +* +* 2 3 +* +.subckt Coax_Gnd_EField ++ 4 5 6 ++ 7 8 9 ++ 2 3 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 4 10 2.201463E-02 +Rdc_c2_e1 5 11 1.830000E-01 +Rdc_c3_e1 6 1 6.100000E-09 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 7 12 2.201463E-02 +Rdc_c2_e2 8 13 1.830000E-01 +Rdc_c3_e2 9 1 6.100000E-09 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 10 16 +Vmeas_domain_decomp_c2_e1 11 18 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 16 17 14 1 1.000000E+00 +E_domain_decomp_c1_dc2_e1 17 1 15 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 18 19 14 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e1 19 1 15 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 14 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc1_e1 1 14 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 15 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 15 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 12 22 +Vmeas_domain_decomp_c2_e2 13 24 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 22 23 20 1 1.000000E+00 +E_domain_decomp_c1_dc2_e2 23 1 21 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 24 25 20 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e2 25 1 21 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 20 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc1_e2 1 20 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 21 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 21 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 14 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 26 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 20 29 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 29 1 28 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 28 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 26 30 4.848574E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 28 31 4.848574E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 30 1 32 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 31 1 33 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m1_e1 33 1 34 1 LEN= 1.220000E+00 ++ R=0.0 L= 2.505526E-07 G=0.0 C= 1.065788E-10 +* +* Delay line for negative z propagation +* +T_mz_d1_m1_e2 32 1 35 1 LEN= 1.220000E+00 ++ R=0.0 L= 2.505526E-07 G=0.0 C= 1.065788E-10 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 33 1 4.848574E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 32 1 4.848574E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 34 36 26 1 2.000000E+00 +E_m_pz_d1_m1_e2 36 1 30 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 35 37 28 1 2.000000E+00 +E_m_mz_d1_m1_e2 37 1 31 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 15 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 38 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 21 41 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 41 1 40 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 40 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 38 44 1.980799E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 40 45 1.980799E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 44 42 46 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 45 43 47 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d2_m1_e1 47 1 48 1 LEN= 1.220000E+00 ++ R=0.0 L= 6.607234E-07 G=0.0 C= 1.683988E-11 +* +* Delay line for negative z propagation +* +T_mz_d2_m1_e2 46 1 49 1 LEN= 1.220000E+00 ++ R=0.0 L= 6.607234E-07 G=0.0 C= 1.683988E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 47 1 1.980799E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 46 1 1.980799E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 48 50 38 1 2.000000E+00 +E_m_pz_d2_m1_e2 50 1 44 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 49 51 40 1 2.000000E+00 +E_m_mz_d2_m1_e2 51 1 45 1 -1.000000E+00 +* +* START OF INCIDENT FIELD EXCITATION MODELS +* +* +* Incident field delay lines, Tz delay +* +T_Tz_Einc 53 1 54 1 LEN= 1.220000E+00 ++ R=0.0 L= 8.339102E-08 G=0.0 C= 3.335641E-11 +* +* Matched impedance: Tz delay +* +RZC_Tz_Einc 54 1 0.500000E+02 +* +* Delay line controlled sources Tz delay +* +E1_Tz_Einc 53 1 2 3 0.100000E+01 +* +* Delay line Tz+T_victim(v_mode) +* +T_TzPTv_EINC_vm_1 55 1 56 1 LEN= 1.220000E+00 ++ R=0.0 L= 2.501731E-07 G=0.0 C= 1.000692E-10 +* +* Matched impedance: Tz+T_victim(v_mode) delay +* +RZC_TzPTv_EINC_vm_1 56 1 0.500000E+02 +* +* Incident field delay line controlled source: Tz+T_victim(v_mode) delay +* +E1_TzPTv_EINC_vm_1 55 1 2 3 0.100000E+01 +* +* Incident field delay line T_victim(v_mode) +* +T_Tv_EINC_vm_1 57 1 58 1 LEN= 1.220000E+00 ++ R=0.0 L= 1.667820E-07 G=0.0 C= 6.671282E-11 +* +* Matched impedance T_victim(v_mode) delay +* +RZC_Tv_EINC_vm_1 58 1 0.500000E+02 +* +* Controlled source for T_victim(v_mode) delay +* +E1_Tv_EINC_vm_1 57 1 2 3 0.100000E+01 +* +* Circuit to combine incident field excitation terms +* +E_zt_dsum_s_EINC_vm_1_E1 59 1 2 3 0.299883E-01 +E_zt_dsum_s_EINC_vm_1_E2 60 59 56 1 -0.299883E-01 +E_zt_dsum_l_EINC_vm_1_E1 61 1 58 1 -0.318364E-02 +E_zt_dsum_l_EINC_vm_1_E2 62 61 54 1 0.318364E-02 +* +* Large resistance to complete the circuit for the series voltage sources +* +R_Einc_dsum_l_EINC_vm_1 62 1 0.100000E+01 +R_Einc_dsum_s_EINC_vm_1 60 1 0.100000E+01 +* +* Incident field excitation sources, end 1 +* +E_Einc_s_EINC_vm_1 42 1 60 1 1.000000E+00 +* +* Incident field excitation sources, end 2 +* +E_Einc_l_EINC_vm_1 43 1 62 1 1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire.spice_model_spec b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire.spice_model_spec new file mode 100644 index 0000000..d826e63 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire.spice_model_spec @@ -0,0 +1,19 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +# MOD_bundle_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +# MOD_spice_bundle_lib_dir +../MOD_WEB_EXAMPLES/SPICE/ +# spice_symbol_dir +../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ +# Specification for spice model of FD_2_Wire +FD_2_Wire +# cable bundle length (m) +1.9 +# Incident field specification +0 amplitude (V/m) +0 0 ktheta kphi (degrees) +0 0 Etheta Ephi (degrees) +# Transfer Impedance Model +0 # number of transfer impedances to include in the model +No_validation_test \ No newline at end of file diff --git a/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_LTspice.lib b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_LTspice.lib new file mode 100644 index 0000000..2698052 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_LTspice.lib @@ -0,0 +1,140 @@ +* LTspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* node: 3 Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* +* End 2 nodes: +* +* node: 4 Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* node: 5 Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* +.subckt FD_2_Wire ++ 2 3 ++ 4 5 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 6 1.666532E-01 +Rdc_c2_e1 3 1 1.666532E-01 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 4 7 1.666532E-01 +Rdc_c2_e2 5 1 1.666532E-01 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 6 9 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 9 1 8 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 8 Vmeas_domain_decomp_c1_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 7 11 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 11 1 10 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 10 Vmeas_domain_decomp_c1_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 8 13 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 13 1 12 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 12 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 10 15 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 15 1 14 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 14 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 12 16 3.305770E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 14 17 3.305770E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 16 1 18 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 17 1 19 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 19 1 20 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 1.102686E-06 C= 1.009036E-11 LEN= 1.900000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 18 1 21 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 1.102686E-06 C= 1.009036E-11 LEN= 1.900000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 19 1 3.305770E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 18 1 3.305770E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 20 22 12 1 2.000000E+00 +E_m_pz_d1_m1_e2 22 1 16 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 21 23 14 1 2.000000E+00 +E_m_mz_d1_m1_e2 23 1 17 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_Ngspice.lib b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_Ngspice.lib new file mode 100644 index 0000000..8343bb3 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_Ngspice.lib @@ -0,0 +1,140 @@ +* Ngspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* node: 3 Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* +* End 2 nodes: +* +* node: 4 Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* node: 5 Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* +.subckt FD_2_Wire ++ 2 3 ++ 4 5 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 6 1.666532E-01 +Rdc_c2_e1 3 1 1.666532E-01 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 4 7 1.666532E-01 +Rdc_c2_e2 5 1 1.666532E-01 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 6 9 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 9 1 8 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 8 Vmeas_domain_decomp_c1_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 7 11 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 11 1 10 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 10 Vmeas_domain_decomp_c1_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 8 13 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 13 1 12 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 12 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 10 15 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 15 1 14 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 14 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 12 16 3.305770E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 14 17 3.305770E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 16 1 18 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 17 1 19 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 19 1 20 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 1.102686E-06 C= 1.009036E-11 LEN= 1.900000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 18 1 21 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 1.102686E-06 C= 1.009036E-11 LEN= 1.900000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 19 1 3.305770E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 18 1 3.305770E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 20 22 12 1 2.000000E+00 +E_m_pz_d1_m1_e2 22 1 16 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 21 23 14 1 2.000000E+00 +E_m_mz_d1_m1_e2 23 1 17 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_PSpice.lib b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_PSpice.lib new file mode 100644 index 0000000..ef3ddae --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/FD_2_Wire_PSpice.lib @@ -0,0 +1,140 @@ +* Pspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* node: 3 Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* +* End 2 nodes: +* +* node: 4 Conductor number 1. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* node: 5 Conductor number 2. Cable name: single_wire. type: cylindrical. conductor 1 : wire +* +.subckt FD_2_Wire ++ 2 3 ++ 4 5 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 6 1.666532E-01 +Rdc_c2_e1 3 1 1.666532E-01 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 4 7 1.666532E-01 +Rdc_c2_e2 5 1 1.666532E-01 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 6 9 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 9 1 8 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 8 Vmeas_domain_decomp_c1_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 7 11 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 11 1 10 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 10 Vmeas_domain_decomp_c1_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 8 13 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 13 1 12 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 12 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 10 15 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 15 1 14 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 14 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 12 16 3.305770E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 14 17 3.305770E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 16 1 18 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 17 1 19 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m1_e1 19 1 20 1 LEN= 1.900000E+00 ++ R=0.0 L= 1.102686E-06 G=0.0 C= 1.009036E-11 +* +* Delay line for negative z propagation +* +T_mz_d1_m1_e2 18 1 21 1 LEN= 1.900000E+00 ++ R=0.0 L= 1.102686E-06 G=0.0 C= 1.009036E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 19 1 3.305770E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 18 1 3.305770E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 20 22 12 1 2.000000E+00 +E_m_pz_d1_m1_e2 22 1 16 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 21 23 14 1 2.000000E+00 +E_m_mz_d1_m1_e2 23 1 17 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Coax_Gnd_EField.asy b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Coax_Gnd_EField.asy new file mode 100644 index 0000000..1aa908c --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Coax_Gnd_EField.asy @@ -0,0 +1,34 @@ +Version 4 +SymbolType CELL +LINE Normal 16 0 16 96 +LINE Normal 16 96 192 96 +LINE Normal 192 96 192 0 +LINE Normal 192 0 16 0 +LINE Normal 0 16 16 16 +LINE Normal 0 48 16 48 +LINE Normal 0 80 16 80 +LINE Normal 208 16 192 16 +LINE Normal 208 48 192 48 +LINE Normal 208 80 192 80 +WINDOW 3 104 -32 centre 0 +SYMATTR Value Coax_Gnd_EField +SYMATTR Prefix X +SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Coax_Gnd_EField_LTspice.lib +PIN 0 16 LEFT 16 +PINATTR PinName c1_e1 +PINATTR SpiceOrder 1 +PIN 0 48 LEFT 16 +PINATTR PinName c2_e1 +PINATTR SpiceOrder 2 +PIN 0 80 LEFT 16 +PINATTR PinName c3_e1 +PINATTR SpiceOrder 3 +PIN 208 16 RIGHT 16 +PINATTR PinName c1_e2 +PINATTR SpiceOrder 4 +PIN 208 48 RIGHT 16 +PINATTR PinName c2_e2 +PINATTR SpiceOrder 5 +PIN 208 80 RIGHT 16 +PINATTR PinName c3_e2 +PINATTR SpiceOrder 6 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Coax_Gnd_EField.sym b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Coax_Gnd_EField.sym new file mode 100644 index 0000000..308e5db --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Coax_Gnd_EField.sym @@ -0,0 +1,85 @@ +v 20050820 1 +L 200 0 200 600 3 0 0 0 -1 -1 +L 200 600 1800 600 3 0 0 0 -1 -1 +L 1800 600 1800 0 3 0 0 0 -1 -1 +L 1800 0 200 0 3 0 0 0 -1 -1 +P 0 500 200 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=1 +T 150 150 5 8 0 0 0 8 1 +pinseq=1 +T 200 500 9 6 1 1 0 1 1 +pinlabel=c1_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 300 200 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=2 +T 150 150 5 8 0 0 0 8 1 +pinseq=2 +T 200 300 9 6 1 1 0 1 1 +pinlabel=c2_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 100 200 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=3 +T 150 150 5 8 0 0 0 8 1 +pinseq=3 +T 200 100 9 6 1 1 0 1 1 +pinlabel=c3_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 500 1800 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=4 +T 150 150 5 8 0 0 0 8 1 +pinseq=4 +T 1800 500 9 6 1 1 0 7 1 +pinlabel=c1_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 300 1800 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=5 +T 150 150 5 8 0 0 0 8 1 +pinseq=5 +T 1800 300 9 6 1 1 0 7 1 +pinlabel=c2_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 100 1800 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=6 +T 150 150 5 8 0 0 0 8 1 +pinseq=6 +T 1800 100 9 6 1 1 0 7 1 +pinlabel=c3_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +T 1000 1000 8 10 1 1 0 4 1 +device=Coax_Gnd_EField +T 1000 800 5 10 1 0 0 4 1 +refdes=X? +T 200 0 8 10 0 0 0 4 1 +description=Coax_Gnd_EField +T 200 0 8 10 0 0 0 0 1 +value=Coax_Gnd_EField +T 200 0 8 10 0 0 0 0 1 +file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Coax_Gnd_EField_Ngspice.lib +T 200 0 8 10 0 0 0 0 1 +numslots=0 +T 200 0 8 10 0 0 0 0 1 +symversion=0.1 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/FD_2_Wire.asy b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/FD_2_Wire.asy new file mode 100644 index 0000000..45618fe --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/FD_2_Wire.asy @@ -0,0 +1,26 @@ +Version 4 +SymbolType CELL +LINE Normal 16 0 16 64 +LINE Normal 16 64 192 64 +LINE Normal 192 64 192 0 +LINE Normal 192 0 16 0 +LINE Normal 0 16 16 16 +LINE Normal 0 48 16 48 +LINE Normal 208 16 192 16 +LINE Normal 208 48 192 48 +WINDOW 3 104 -32 centre 0 +SYMATTR Value FD_2_Wire +SYMATTR Prefix X +SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/FD_2_Wire_LTspice.lib +PIN 0 16 LEFT 16 +PINATTR PinName c1_e1 +PINATTR SpiceOrder 1 +PIN 0 48 LEFT 16 +PINATTR PinName c2_e1 +PINATTR SpiceOrder 2 +PIN 208 16 RIGHT 16 +PINATTR PinName c1_e2 +PINATTR SpiceOrder 3 +PIN 208 48 RIGHT 16 +PINATTR PinName c2_e2 +PINATTR SpiceOrder 4 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/FD_2_Wire.sym b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/FD_2_Wire.sym new file mode 100644 index 0000000..d088e5b --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/FD_2_Wire.sym @@ -0,0 +1,63 @@ +v 20050820 1 +L 200 0 200 400 3 0 0 0 -1 -1 +L 200 400 1800 400 3 0 0 0 -1 -1 +L 1800 400 1800 0 3 0 0 0 -1 -1 +L 1800 0 200 0 3 0 0 0 -1 -1 +P 0 300 200 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=1 +T 150 150 5 8 0 0 0 8 1 +pinseq=1 +T 200 300 9 6 1 1 0 1 1 +pinlabel=c1_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 100 200 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=2 +T 150 150 5 8 0 0 0 8 1 +pinseq=2 +T 200 100 9 6 1 1 0 1 1 +pinlabel=c2_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 300 1800 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=3 +T 150 150 5 8 0 0 0 8 1 +pinseq=3 +T 1800 300 9 6 1 1 0 7 1 +pinlabel=c1_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 100 1800 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=4 +T 150 150 5 8 0 0 0 8 1 +pinseq=4 +T 1800 100 9 6 1 1 0 7 1 +pinlabel=c2_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +T 1000 800 8 10 1 1 0 4 1 +device=FD_2_Wire +T 1000 600 5 10 1 0 0 4 1 +refdes=X? +T 200 0 8 10 0 0 0 4 1 +description=FD_2_Wire +T 200 0 8 10 0 0 0 0 1 +value=FD_2_Wire +T 200 0 8 10 0 0 0 0 1 +file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/FD_2_Wire_Ngspice.lib +T 200 0 8 10 0 0 0 0 1 +numslots=0 +T 200 0 8 10 0 0 0 0 1 +symversion=0.1 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Twisted_Pair_Over_Ground.asy b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Twisted_Pair_Over_Ground.asy new file mode 100644 index 0000000..9f2e3b3 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Twisted_Pair_Over_Ground.asy @@ -0,0 +1,34 @@ +Version 4 +SymbolType CELL +LINE Normal 16 0 16 96 +LINE Normal 16 96 192 96 +LINE Normal 192 96 192 0 +LINE Normal 192 0 16 0 +LINE Normal 0 16 16 16 +LINE Normal 0 48 16 48 +LINE Normal 0 80 16 80 +LINE Normal 208 16 192 16 +LINE Normal 208 48 192 48 +LINE Normal 208 80 192 80 +WINDOW 3 104 -32 centre 0 +SYMATTR Value Twisted_Pair_Over_Ground +SYMATTR Prefix X +SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Twisted_Pair_Over_Ground_LTspice.lib +PIN 0 16 LEFT 16 +PINATTR PinName c1_e1 +PINATTR SpiceOrder 1 +PIN 0 48 LEFT 16 +PINATTR PinName c2_e1 +PINATTR SpiceOrder 2 +PIN 0 80 LEFT 16 +PINATTR PinName c3_e1 +PINATTR SpiceOrder 3 +PIN 208 16 RIGHT 16 +PINATTR PinName c1_e2 +PINATTR SpiceOrder 4 +PIN 208 48 RIGHT 16 +PINATTR PinName c2_e2 +PINATTR SpiceOrder 5 +PIN 208 80 RIGHT 16 +PINATTR PinName c3_e2 +PINATTR SpiceOrder 6 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Twisted_Pair_Over_Ground.sym b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Twisted_Pair_Over_Ground.sym new file mode 100644 index 0000000..3c26b86 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/Twisted_Pair_Over_Ground.sym @@ -0,0 +1,85 @@ +v 20050820 1 +L 200 0 200 600 3 0 0 0 -1 -1 +L 200 600 1800 600 3 0 0 0 -1 -1 +L 1800 600 1800 0 3 0 0 0 -1 -1 +L 1800 0 200 0 3 0 0 0 -1 -1 +P 0 500 200 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=1 +T 150 150 5 8 0 0 0 8 1 +pinseq=1 +T 200 500 9 6 1 1 0 1 1 +pinlabel=c1_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 300 200 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=2 +T 150 150 5 8 0 0 0 8 1 +pinseq=2 +T 200 300 9 6 1 1 0 1 1 +pinlabel=c2_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 100 200 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=3 +T 150 150 5 8 0 0 0 8 1 +pinseq=3 +T 200 100 9 6 1 1 0 1 1 +pinlabel=c3_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 500 1800 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=4 +T 150 150 5 8 0 0 0 8 1 +pinseq=4 +T 1800 500 9 6 1 1 0 7 1 +pinlabel=c1_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 300 1800 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=5 +T 150 150 5 8 0 0 0 8 1 +pinseq=5 +T 1800 300 9 6 1 1 0 7 1 +pinlabel=c2_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 100 1800 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=6 +T 150 150 5 8 0 0 0 8 1 +pinseq=6 +T 1800 100 9 6 1 1 0 7 1 +pinlabel=c3_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +T 1000 1000 8 10 1 1 0 4 1 +device=Twisted_Pair_Over_Ground +T 1000 800 5 10 1 0 0 4 1 +refdes=X? +T 200 0 8 10 0 0 0 4 1 +description=Twisted_Pair_Over_Ground +T 200 0 8 10 0 0 0 0 1 +value=Twisted_Pair_Over_Ground +T 200 0 8 10 0 0 0 0 1 +file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/Twisted_Pair_Over_Ground_Ngspice.lib +T 200 0 8 10 0 0 0 0 1 +numslots=0 +T 200 0 8 10 0 0 0 0 1 +symversion=0.1 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Coax.asy b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Coax.asy new file mode 100644 index 0000000..bd09abc --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Coax.asy @@ -0,0 +1,34 @@ +Version 4 +SymbolType CELL +LINE Normal 16 0 16 96 +LINE Normal 16 96 192 96 +LINE Normal 192 96 192 0 +LINE Normal 192 0 16 0 +LINE Normal 0 16 16 16 +LINE Normal 0 48 16 48 +LINE Normal 0 80 16 80 +LINE Normal 208 16 192 16 +LINE Normal 208 48 192 48 +LINE Normal 208 80 192 80 +WINDOW 3 104 -32 centre 0 +SYMATTR Value ZT_FD_Coax +SYMATTR Prefix X +SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Coax_LTspice.lib +PIN 0 16 LEFT 16 +PINATTR PinName c1_e1 +PINATTR SpiceOrder 1 +PIN 0 48 LEFT 16 +PINATTR PinName c2_e1 +PINATTR SpiceOrder 2 +PIN 0 80 LEFT 16 +PINATTR PinName c3_e1 +PINATTR SpiceOrder 3 +PIN 208 16 RIGHT 16 +PINATTR PinName c1_e2 +PINATTR SpiceOrder 4 +PIN 208 48 RIGHT 16 +PINATTR PinName c2_e2 +PINATTR SpiceOrder 5 +PIN 208 80 RIGHT 16 +PINATTR PinName c3_e2 +PINATTR SpiceOrder 6 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Coax.sym b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Coax.sym new file mode 100644 index 0000000..8becdaf --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Coax.sym @@ -0,0 +1,85 @@ +v 20050820 1 +L 200 0 200 600 3 0 0 0 -1 -1 +L 200 600 1800 600 3 0 0 0 -1 -1 +L 1800 600 1800 0 3 0 0 0 -1 -1 +L 1800 0 200 0 3 0 0 0 -1 -1 +P 0 500 200 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=1 +T 150 150 5 8 0 0 0 8 1 +pinseq=1 +T 200 500 9 6 1 1 0 1 1 +pinlabel=c1_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 300 200 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=2 +T 150 150 5 8 0 0 0 8 1 +pinseq=2 +T 200 300 9 6 1 1 0 1 1 +pinlabel=c2_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 100 200 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=3 +T 150 150 5 8 0 0 0 8 1 +pinseq=3 +T 200 100 9 6 1 1 0 1 1 +pinlabel=c3_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 500 1800 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=4 +T 150 150 5 8 0 0 0 8 1 +pinseq=4 +T 1800 500 9 6 1 1 0 7 1 +pinlabel=c1_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 300 1800 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=5 +T 150 150 5 8 0 0 0 8 1 +pinseq=5 +T 1800 300 9 6 1 1 0 7 1 +pinlabel=c2_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 100 1800 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=6 +T 150 150 5 8 0 0 0 8 1 +pinseq=6 +T 1800 100 9 6 1 1 0 7 1 +pinlabel=c3_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +T 1000 1000 8 10 1 1 0 4 1 +device=ZT_FD_Coax +T 1000 800 5 10 1 0 0 4 1 +refdes=X? +T 200 0 8 10 0 0 0 4 1 +description=ZT_FD_Coax +T 200 0 8 10 0 0 0 0 1 +value=ZT_FD_Coax +T 200 0 8 10 0 0 0 0 1 +file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Coax_Ngspice.lib +T 200 0 8 10 0 0 0 0 1 +numslots=0 +T 200 0 8 10 0 0 0 0 1 +symversion=0.1 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Spacewire.asy b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Spacewire.asy new file mode 100644 index 0000000..a6113dd --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Spacewire.asy @@ -0,0 +1,114 @@ +Version 4 +SymbolType CELL +LINE Normal 16 0 16 416 +LINE Normal 16 416 192 416 +LINE Normal 192 416 192 0 +LINE Normal 192 0 16 0 +LINE Normal 0 16 16 16 +LINE Normal 0 48 16 48 +LINE Normal 0 80 16 80 +LINE Normal 0 112 16 112 +LINE Normal 0 144 16 144 +LINE Normal 0 176 16 176 +LINE Normal 0 208 16 208 +LINE Normal 0 240 16 240 +LINE Normal 0 272 16 272 +LINE Normal 0 304 16 304 +LINE Normal 0 336 16 336 +LINE Normal 0 368 16 368 +LINE Normal 0 400 16 400 +LINE Normal 208 16 192 16 +LINE Normal 208 48 192 48 +LINE Normal 208 80 192 80 +LINE Normal 208 112 192 112 +LINE Normal 208 144 192 144 +LINE Normal 208 176 192 176 +LINE Normal 208 208 192 208 +LINE Normal 208 240 192 240 +LINE Normal 208 272 192 272 +LINE Normal 208 304 192 304 +LINE Normal 208 336 192 336 +LINE Normal 208 368 192 368 +LINE Normal 208 400 192 400 +WINDOW 3 104 -32 centre 0 +SYMATTR Value ZT_FD_Spacewire +SYMATTR Prefix X +SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Spacewire_LTspice.lib +PIN 0 16 LEFT 16 +PINATTR PinName c1_e1 +PINATTR SpiceOrder 1 +PIN 0 48 LEFT 16 +PINATTR PinName c2_e1 +PINATTR SpiceOrder 2 +PIN 0 80 LEFT 16 +PINATTR PinName c3_e1 +PINATTR SpiceOrder 3 +PIN 0 112 LEFT 16 +PINATTR PinName c4_e1 +PINATTR SpiceOrder 4 +PIN 0 144 LEFT 16 +PINATTR PinName c5_e1 +PINATTR SpiceOrder 5 +PIN 0 176 LEFT 16 +PINATTR PinName c6_e1 +PINATTR SpiceOrder 6 +PIN 0 208 LEFT 16 +PINATTR PinName c7_e1 +PINATTR SpiceOrder 7 +PIN 0 240 LEFT 16 +PINATTR PinName c8_e1 +PINATTR SpiceOrder 8 +PIN 0 272 LEFT 16 +PINATTR PinName c9_e1 +PINATTR SpiceOrder 9 +PIN 0 304 LEFT 16 +PINATTR PinName c10_e1 +PINATTR SpiceOrder 10 +PIN 0 336 LEFT 16 +PINATTR PinName c11_e1 +PINATTR SpiceOrder 11 +PIN 0 368 LEFT 16 +PINATTR PinName c12_e1 +PINATTR SpiceOrder 12 +PIN 0 400 LEFT 16 +PINATTR PinName c13_e1 +PINATTR SpiceOrder 13 +PIN 208 16 RIGHT 16 +PINATTR PinName c1_e2 +PINATTR SpiceOrder 14 +PIN 208 48 RIGHT 16 +PINATTR PinName c2_e2 +PINATTR SpiceOrder 15 +PIN 208 80 RIGHT 16 +PINATTR PinName c3_e2 +PINATTR SpiceOrder 16 +PIN 208 112 RIGHT 16 +PINATTR PinName c4_e2 +PINATTR SpiceOrder 17 +PIN 208 144 RIGHT 16 +PINATTR PinName c5_e2 +PINATTR SpiceOrder 18 +PIN 208 176 RIGHT 16 +PINATTR PinName c6_e2 +PINATTR SpiceOrder 19 +PIN 208 208 RIGHT 16 +PINATTR PinName c7_e2 +PINATTR SpiceOrder 20 +PIN 208 240 RIGHT 16 +PINATTR PinName c8_e2 +PINATTR SpiceOrder 21 +PIN 208 272 RIGHT 16 +PINATTR PinName c9_e2 +PINATTR SpiceOrder 22 +PIN 208 304 RIGHT 16 +PINATTR PinName c10_e2 +PINATTR SpiceOrder 23 +PIN 208 336 RIGHT 16 +PINATTR PinName c11_e2 +PINATTR SpiceOrder 24 +PIN 208 368 RIGHT 16 +PINATTR PinName c12_e2 +PINATTR SpiceOrder 25 +PIN 208 400 RIGHT 16 +PINATTR PinName c13_e2 +PINATTR SpiceOrder 26 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Spacewire.sym b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Spacewire.sym new file mode 100644 index 0000000..e5316ab --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Spacewire.sym @@ -0,0 +1,305 @@ +v 20050820 1 +L 200 0 200 2600 3 0 0 0 -1 -1 +L 200 2600 1800 2600 3 0 0 0 -1 -1 +L 1800 2600 1800 0 3 0 0 0 -1 -1 +L 1800 0 200 0 3 0 0 0 -1 -1 +P 0 2500 200 2500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=1 +T 150 150 5 8 0 0 0 8 1 +pinseq=1 +T 200 2500 9 6 1 1 0 1 1 +pinlabel=c1_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 2300 200 2300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=2 +T 150 150 5 8 0 0 0 8 1 +pinseq=2 +T 200 2300 9 6 1 1 0 1 1 +pinlabel=c2_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 2100 200 2100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=3 +T 150 150 5 8 0 0 0 8 1 +pinseq=3 +T 200 2100 9 6 1 1 0 1 1 +pinlabel=c3_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 1900 200 1900 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=4 +T 150 150 5 8 0 0 0 8 1 +pinseq=4 +T 200 1900 9 6 1 1 0 1 1 +pinlabel=c4_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 1700 200 1700 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=5 +T 150 150 5 8 0 0 0 8 1 +pinseq=5 +T 200 1700 9 6 1 1 0 1 1 +pinlabel=c5_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 1500 200 1500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=6 +T 150 150 5 8 0 0 0 8 1 +pinseq=6 +T 200 1500 9 6 1 1 0 1 1 +pinlabel=c6_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 1300 200 1300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=7 +T 150 150 5 8 0 0 0 8 1 +pinseq=7 +T 200 1300 9 6 1 1 0 1 1 +pinlabel=c7_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 1100 200 1100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=8 +T 150 150 5 8 0 0 0 8 1 +pinseq=8 +T 200 1100 9 6 1 1 0 1 1 +pinlabel=c8_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 900 200 900 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=9 +T 150 150 5 8 0 0 0 8 1 +pinseq=9 +T 200 900 9 6 1 1 0 1 1 +pinlabel=c9_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 700 200 700 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=10 +T 150 150 5 8 0 0 0 8 1 +pinseq=10 +T 200 700 9 6 1 1 0 1 1 +pinlabel=c10_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 500 200 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=11 +T 150 150 5 8 0 0 0 8 1 +pinseq=11 +T 200 500 9 6 1 1 0 1 1 +pinlabel=c11_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 300 200 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=12 +T 150 150 5 8 0 0 0 8 1 +pinseq=12 +T 200 300 9 6 1 1 0 1 1 +pinlabel=c12_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 100 200 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=13 +T 150 150 5 8 0 0 0 8 1 +pinseq=13 +T 200 100 9 6 1 1 0 1 1 +pinlabel=c13_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 2500 1800 2500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=14 +T 150 150 5 8 0 0 0 8 1 +pinseq=14 +T 1800 2500 9 6 1 1 0 7 1 +pinlabel=c1_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 2300 1800 2300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=15 +T 150 150 5 8 0 0 0 8 1 +pinseq=15 +T 1800 2300 9 6 1 1 0 7 1 +pinlabel=c2_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 2100 1800 2100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=16 +T 150 150 5 8 0 0 0 8 1 +pinseq=16 +T 1800 2100 9 6 1 1 0 7 1 +pinlabel=c3_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 1900 1800 1900 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=17 +T 150 150 5 8 0 0 0 8 1 +pinseq=17 +T 1800 1900 9 6 1 1 0 7 1 +pinlabel=c4_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 1700 1800 1700 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=18 +T 150 150 5 8 0 0 0 8 1 +pinseq=18 +T 1800 1700 9 6 1 1 0 7 1 +pinlabel=c5_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 1500 1800 1500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=19 +T 150 150 5 8 0 0 0 8 1 +pinseq=19 +T 1800 1500 9 6 1 1 0 7 1 +pinlabel=c6_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 1300 1800 1300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=20 +T 150 150 5 8 0 0 0 8 1 +pinseq=20 +T 1800 1300 9 6 1 1 0 7 1 +pinlabel=c7_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 1100 1800 1100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=21 +T 150 150 5 8 0 0 0 8 1 +pinseq=21 +T 1800 1100 9 6 1 1 0 7 1 +pinlabel=c8_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 900 1800 900 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=22 +T 150 150 5 8 0 0 0 8 1 +pinseq=22 +T 1800 900 9 6 1 1 0 7 1 +pinlabel=c9_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 700 1800 700 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=23 +T 150 150 5 8 0 0 0 8 1 +pinseq=23 +T 1800 700 9 6 1 1 0 7 1 +pinlabel=c10_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 500 1800 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=24 +T 150 150 5 8 0 0 0 8 1 +pinseq=24 +T 1800 500 9 6 1 1 0 7 1 +pinlabel=c11_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 300 1800 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=25 +T 150 150 5 8 0 0 0 8 1 +pinseq=25 +T 1800 300 9 6 1 1 0 7 1 +pinlabel=c12_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 100 1800 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=26 +T 150 150 5 8 0 0 0 8 1 +pinseq=26 +T 1800 100 9 6 1 1 0 7 1 +pinlabel=c13_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +T 1000 3000 8 10 1 1 0 4 1 +device=ZT_FD_Spacewire +T 1000 2800 5 10 1 0 0 4 1 +refdes=X? +T 200 0 8 10 0 0 0 4 1 +description=ZT_FD_Spacewire +T 200 0 8 10 0 0 0 0 1 +value=ZT_FD_Spacewire +T 200 0 8 10 0 0 0 0 1 +file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Spacewire_Ngspice.lib +T 200 0 8 10 0 0 0 0 1 +numslots=0 +T 200 0 8 10 0 0 0 0 1 +symversion=0.1 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Twinax.asy b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Twinax.asy new file mode 100644 index 0000000..83c4a99 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Twinax.asy @@ -0,0 +1,34 @@ +Version 4 +SymbolType CELL +LINE Normal 16 0 16 96 +LINE Normal 16 96 192 96 +LINE Normal 192 96 192 0 +LINE Normal 192 0 16 0 +LINE Normal 0 16 16 16 +LINE Normal 0 48 16 48 +LINE Normal 0 80 16 80 +LINE Normal 208 16 192 16 +LINE Normal 208 48 192 48 +LINE Normal 208 80 192 80 +WINDOW 3 104 -32 centre 0 +SYMATTR Value ZT_FD_Twinax +SYMATTR Prefix X +SYMATTR ModelFile PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Twinax_LTspice.lib +PIN 0 16 LEFT 16 +PINATTR PinName c1_e1 +PINATTR SpiceOrder 1 +PIN 0 48 LEFT 16 +PINATTR PinName c2_e1 +PINATTR SpiceOrder 2 +PIN 0 80 LEFT 16 +PINATTR PinName c3_e1 +PINATTR SpiceOrder 3 +PIN 208 16 RIGHT 16 +PINATTR PinName c1_e2 +PINATTR SpiceOrder 4 +PIN 208 48 RIGHT 16 +PINATTR PinName c2_e2 +PINATTR SpiceOrder 5 +PIN 208 80 RIGHT 16 +PINATTR PinName c3_e2 +PINATTR SpiceOrder 6 diff --git a/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Twinax.sym b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Twinax.sym new file mode 100644 index 0000000..ee4dd11 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/SYMBOL/ZT_FD_Twinax.sym @@ -0,0 +1,85 @@ +v 20050820 1 +L 200 0 200 600 3 0 0 0 -1 -1 +L 200 600 1800 600 3 0 0 0 -1 -1 +L 1800 600 1800 0 3 0 0 0 -1 -1 +L 1800 0 200 0 3 0 0 0 -1 -1 +P 0 500 200 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=1 +T 150 150 5 8 0 0 0 8 1 +pinseq=1 +T 200 500 9 6 1 1 0 1 1 +pinlabel=c1_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 300 200 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=2 +T 150 150 5 8 0 0 0 8 1 +pinseq=2 +T 200 300 9 6 1 1 0 1 1 +pinlabel=c2_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 0 100 200 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=3 +T 150 150 5 8 0 0 0 8 1 +pinseq=3 +T 200 100 9 6 1 1 0 1 1 +pinlabel=c3_e1 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 500 1800 500 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=4 +T 150 150 5 8 0 0 0 8 1 +pinseq=4 +T 1800 500 9 6 1 1 0 7 1 +pinlabel=c1_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 300 1800 300 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=5 +T 150 150 5 8 0 0 0 8 1 +pinseq=5 +T 1800 300 9 6 1 1 0 7 1 +pinlabel=c2_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +P 2000 100 1800 100 1 0 0 +{ +T 150 250 5 8 0 0 0 6 1 +pinnumber=6 +T 150 150 5 8 0 0 0 8 1 +pinseq=6 +T 1800 100 9 6 1 1 0 7 1 +pinlabel=c3_e2 +T 200 200 5 8 0 0 0 2 1 +pintype=pas +} +T 1000 1000 8 10 1 1 0 4 1 +device=ZT_FD_Twinax +T 1000 800 5 10 1 0 0 4 1 +refdes=X? +T 200 0 8 10 0 0 0 4 1 +description=ZT_FD_Twinax +T 200 0 8 10 0 0 0 0 1 +value=ZT_FD_Twinax +T 200 0 8 10 0 0 0 0 1 +file=PATH_TO_TRANSMISSION_LINE_SUB_CIRCUITS/ZT_FD_Twinax_Ngspice.lib +T 200 0 8 10 0 0 0 0 1 +numslots=0 +T 200 0 8 10 0 0 0 0 1 +symversion=0.1 diff --git a/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground.spice_model_spec b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground.spice_model_spec new file mode 100644 index 0000000..8168b0b --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground.spice_model_spec @@ -0,0 +1,19 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +# MOD_bundle_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +# MOD_spice_bundle_lib_dir +../MOD_WEB_EXAMPLES/SPICE/ +# spice_symbol_dir +../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ +# Specification for spice model of Twisted_Pair_Over_Ground +Twisted_Pair_Over_Ground +# cable bundle length (m) +1.0 +# Incident field specification +0 amplitude (V/m) +0 0 ktheta kphi (degrees) +0 0 Etheta Ephi (degrees) +# Transfer Impedance Model +0 # number of transfer impedances to include in the model +No_validation_test \ No newline at end of file diff --git a/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_LTspice.lib b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_LTspice.lib new file mode 100644 index 0000000..203d7d0 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_LTspice.lib @@ -0,0 +1,232 @@ +* LTspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 +* node: 3 Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 +* node: 4 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 +* node: 6 Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 +* node: 7 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +.subckt Twisted_Pair_Over_Ground ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.000000E-09 +Rdc_c2_e1 3 9 5.000000E-09 +Rdc_c3_e1 4 1 5.000000E-09 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.000000E-09 +Rdc_c2_e2 6 11 5.000000E-09 +Rdc_c3_e2 7 1 5.000000E-09 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 5.000000E-01 +E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 5.000000E-01 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 -5.000000E-01 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 5.000000E-01 +E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 5.000000E-01 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 -5.000000E-01 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 25 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 28 1.591023E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 26 29 1.591023E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 28 1 30 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 29 1 31 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 31 1 32 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 5.307080E-07 C= 2.096539E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 30 1 33 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 5.307080E-07 C= 2.096539E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 31 1 1.591023E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 30 1 1.591023E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 +E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 13 37 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 19 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 36 40 1.889086E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 38 41 1.889086E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 40 1 42 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 41 1 43 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 43 1 44 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 6.301311E-07 C= 1.765744E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 42 1 45 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 6.301311E-07 C= 1.765744E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 43 1 1.889086E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 42 1 1.889086E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 +E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 +E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_Ngspice.lib b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_Ngspice.lib new file mode 100644 index 0000000..db7663a --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_Ngspice.lib @@ -0,0 +1,232 @@ +* Ngspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 +* node: 3 Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 +* node: 4 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 +* node: 6 Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 +* node: 7 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +.subckt Twisted_Pair_Over_Ground ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.000000E-09 +Rdc_c2_e1 3 9 5.000000E-09 +Rdc_c3_e1 4 1 5.000000E-09 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.000000E-09 +Rdc_c2_e2 6 11 5.000000E-09 +Rdc_c3_e2 7 1 5.000000E-09 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 5.000000E-01 +E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 5.000000E-01 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 -5.000000E-01 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 5.000000E-01 +E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 5.000000E-01 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 -5.000000E-01 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 25 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 28 1.591023E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 26 29 1.591023E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 28 1 30 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 29 1 31 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 31 1 32 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 5.307080E-07 C= 2.096539E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 30 1 33 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 5.307080E-07 C= 2.096539E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 31 1 1.591023E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 30 1 1.591023E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 +E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 13 37 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 19 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 36 40 1.889086E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 38 41 1.889086E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 40 1 42 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 41 1 43 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 43 1 44 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 6.301311E-07 C= 1.765744E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 42 1 45 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 6.301311E-07 C= 1.765744E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 43 1 1.889086E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 42 1 1.889086E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 +E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 +E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_PSpice.lib b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_PSpice.lib new file mode 100644 index 0000000..977fb8d --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/Twisted_Pair_Over_Ground_PSpice.lib @@ -0,0 +1,232 @@ +* Pspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 +* node: 3 Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 +* node: 4 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: twisted_pair. type: twisted_pair. conductor 1 : Twisted pair wire 1 +* node: 6 Conductor number 2. Cable name: twisted_pair. type: twisted_pair. conductor 2 : Twisted pair wire 2 +* node: 7 Conductor number 3. Cable name: ground plane. type: ground_plane. conductor 1 : ground plane +* +.subckt Twisted_Pair_Over_Ground ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.000000E-09 +Rdc_c2_e1 3 9 5.000000E-09 +Rdc_c3_e1 4 1 5.000000E-09 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.000000E-09 +Rdc_c2_e2 6 11 5.000000E-09 +Rdc_c3_e2 7 1 5.000000E-09 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 5.000000E-01 +E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 5.000000E-01 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 -5.000000E-01 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 5.000000E-01 +E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 5.000000E-01 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 -5.000000E-01 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 25 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 28 1.591023E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 26 29 1.591023E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 28 1 30 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 29 1 31 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m1_e1 31 1 32 1 LEN= 1.000000E+00 ++ R=0.0 L= 5.307080E-07 G=0.0 C= 2.096539E-11 +* +* Delay line for negative z propagation +* +T_mz_d1_m1_e2 30 1 33 1 LEN= 1.000000E+00 ++ R=0.0 L= 5.307080E-07 G=0.0 C= 2.096539E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 31 1 1.591023E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 30 1 1.591023E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 +E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 13 37 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 19 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 36 40 1.889086E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 38 41 1.889086E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 40 1 42 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 41 1 43 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d2_m1_e1 43 1 44 1 LEN= 1.000000E+00 ++ R=0.0 L= 6.301311E-07 G=0.0 C= 1.765744E-11 +* +* Delay line for negative z propagation +* +T_mz_d2_m1_e2 42 1 45 1 LEN= 1.000000E+00 ++ R=0.0 L= 6.301311E-07 G=0.0 C= 1.765744E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 43 1 1.889086E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 42 1 1.889086E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 +E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 +E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax.spice_model_spec b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax.spice_model_spec new file mode 100644 index 0000000..60d353b --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax.spice_model_spec @@ -0,0 +1,19 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +# MOD_bundle_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +# MOD_spice_bundle_lib_dir +../MOD_WEB_EXAMPLES/SPICE/ +# spice_symbol_dir +../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ +# Specification for spice model of ZT_FD_Coax +ZT_FD_Coax +# cable bundle length (m) +1.0 +# Incident field specification +0 amplitude (V/m) +0 0 ktheta kphi (degrees) +0 0 Etheta Ephi (degrees) +# Transfer Impedance Model +0 # number of transfer impedances to include in the model +No_validation_test \ No newline at end of file diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_LTspice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_LTspice.lib new file mode 100644 index 0000000..1a662c1 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_LTspice.lib @@ -0,0 +1,232 @@ +* LTspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire +* node: 3 Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire +* node: 4 Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire +* node: 6 Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire +* node: 7 Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield +* +.subckt ZT_FD_Coax ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.000000E-09 +Rdc_c2_e1 3 9 1.804478E-02 +Rdc_c3_e1 4 1 5.000000E-02 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.000000E-09 +Rdc_c2_e2 6 11 1.804478E-02 +Rdc_c3_e2 7 1 5.000000E-02 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 -0.000000E+00 +E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 1.000000E+00 +E_domain_decomp_c2_dc2_e1 17 1 13 1 -0.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 0.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 -0.000000E+00 +E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 1.000000E+00 +E_domain_decomp_c2_dc2_e2 23 1 19 1 -0.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 0.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 25 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 28 4.848574E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 26 29 4.848574E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 28 1 30 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 29 1 31 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 31 1 32 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 30 1 33 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 31 1 4.848574E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 30 1 4.848574E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 +E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 13 37 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 19 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 36 40 3.910788E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 38 41 3.910788E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 40 1 42 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 41 1 43 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 43 1 44 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 1.304499E-06 C= 8.529331E-12 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 42 1 45 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 1.304499E-06 C= 8.529331E-12 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 43 1 3.910788E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 42 1 3.910788E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 +E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 +E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_Ngspice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_Ngspice.lib new file mode 100644 index 0000000..6e2b731 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_Ngspice.lib @@ -0,0 +1,232 @@ +* Ngspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire +* node: 3 Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire +* node: 4 Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire +* node: 6 Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire +* node: 7 Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield +* +.subckt ZT_FD_Coax ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.000000E-09 +Rdc_c2_e1 3 9 1.804478E-02 +Rdc_c3_e1 4 1 5.000000E-02 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.000000E-09 +Rdc_c2_e2 6 11 1.804478E-02 +Rdc_c3_e2 7 1 5.000000E-02 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 -0.000000E+00 +E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 1.000000E+00 +E_domain_decomp_c2_dc2_e1 17 1 13 1 -0.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 0.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 -0.000000E+00 +E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 1.000000E+00 +E_domain_decomp_c2_dc2_e2 23 1 19 1 -0.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 0.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 25 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 28 4.848574E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 26 29 4.848574E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 28 1 30 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 29 1 31 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 31 1 32 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 30 1 33 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 2.505526E-07 C= 1.065788E-10 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 31 1 4.848574E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 30 1 4.848574E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 +E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 13 37 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 19 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 36 40 3.910788E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 38 41 3.910788E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 40 1 42 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 41 1 43 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 43 1 44 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 1.304499E-06 C= 8.529331E-12 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 42 1 45 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 1.304499E-06 C= 8.529331E-12 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 43 1 3.910788E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 42 1 3.910788E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 +E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 +E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_PSpice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_PSpice.lib new file mode 100644 index 0000000..10b43b4 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Coax_PSpice.lib @@ -0,0 +1,232 @@ +* Pspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire +* node: 3 Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire +* node: 4 Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: bare_wire. type: cylindrical. conductor 1 : wire +* node: 6 Conductor number 2. Cable name: coaxial_cable_01. type: coax. conductor 1 : Inner wire +* node: 7 Conductor number 3. Cable name: coaxial_cable_01. type: coax. conductor 2 : Shield +* +.subckt ZT_FD_Coax ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.000000E-09 +Rdc_c2_e1 3 9 1.804478E-02 +Rdc_c3_e1 4 1 5.000000E-02 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.000000E-09 +Rdc_c2_e2 6 11 1.804478E-02 +Rdc_c3_e2 7 1 5.000000E-02 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 -0.000000E+00 +E_domain_decomp_c1_dc2_e1 15 1 13 1 1.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 1.000000E+00 +E_domain_decomp_c2_dc2_e1 17 1 13 1 -0.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 0.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 -0.000000E+00 +E_domain_decomp_c1_dc2_e2 21 1 19 1 1.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 1.000000E+00 +E_domain_decomp_c2_dc2_e2 23 1 19 1 -0.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 0.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 25 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 25 1 24 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 27 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 27 1 26 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 26 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 28 4.848574E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 26 29 4.848574E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 28 1 30 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 29 1 31 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m1_e1 31 1 32 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.505526E-07 G=0.0 C= 1.065788E-10 +* +* Delay line for negative z propagation +* +T_mz_d1_m1_e2 30 1 33 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.505526E-07 G=0.0 C= 1.065788E-10 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 31 1 4.848574E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 30 1 4.848574E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 32 34 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 34 1 28 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 33 35 26 1 2.000000E+00 +E_m_mz_d1_m1_e2 35 1 29 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 13 37 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 37 1 36 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 36 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 19 39 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 39 1 38 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 38 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 36 40 3.910788E+02 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 38 41 3.910788E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 40 1 42 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 41 1 43 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d2_m1_e1 43 1 44 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.304499E-06 G=0.0 C= 8.529331E-12 +* +* Delay line for negative z propagation +* +T_mz_d2_m1_e2 42 1 45 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.304499E-06 G=0.0 C= 8.529331E-12 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 43 1 3.910788E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 42 1 3.910788E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 44 46 36 1 2.000000E+00 +E_m_pz_d2_m1_e2 46 1 40 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 45 47 38 1 2.000000E+00 +E_m_mz_d2_m1_e2 47 1 41 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire.spice_model_spec b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire.spice_model_spec new file mode 100644 index 0000000..40138bc --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire.spice_model_spec @@ -0,0 +1,19 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +# MOD_bundle_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +# MOD_spice_bundle_lib_dir +../MOD_WEB_EXAMPLES/SPICE/ +# spice_symbol_dir +../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ +# Specification for spice model of ZT_FD_Spacewire +FD_ZT_Spacewire +# cable bundle length (m) +1.0 +# Incident field specification +0 amplitude (V/m) +0 0 ktheta kphi (degrees) +0 0 Etheta Ephi (degrees) +# Transfer Impedance Model +0 # number of transfer impedances to include in the model +No_validation_test \ No newline at end of file diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_LTspice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_LTspice.lib new file mode 100644 index 0000000..5f1892c --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_LTspice.lib @@ -0,0 +1,1568 @@ +* LTspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 +* node: 3 Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 +* node: 4 Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 +* node: 5 Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 +* node: 6 Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 +* node: 7 Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 +* node: 8 Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 +* node: 9 Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 +* node: 10 Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 +* node: 11 Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 +* node: 12 Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 +* node: 13 Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 +* node: 14 Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield +* +* End 2 nodes: +* +* node: 15 Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 +* node: 16 Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 +* node: 17 Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 +* node: 18 Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 +* node: 19 Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 +* node: 20 Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 +* node: 21 Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 +* node: 22 Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 +* node: 23 Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 +* node: 24 Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 +* node: 25 Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 +* node: 26 Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 +* node: 27 Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield +* +.subckt ZT_FD_Spacewire ++ 2 3 4 5 6 7 8 9 10 11 12 13 14 ++ 15 16 17 18 19 20 21 22 23 24 25 26 27 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 28 5.092958E-02 +Rdc_c2_e1 3 29 5.092958E-02 +Rdc_c3_e1 4 30 5.092958E-02 +Rdc_c4_e1 5 31 5.092958E-02 +Rdc_c5_e1 6 32 5.092958E-02 +Rdc_c6_e1 7 33 5.092958E-02 +Rdc_c7_e1 8 34 5.092958E-02 +Rdc_c8_e1 9 35 5.092958E-02 +Rdc_c9_e1 10 36 1.273240E-02 +Rdc_c10_e1 11 37 1.273240E-02 +Rdc_c11_e1 12 38 1.273240E-02 +Rdc_c12_e1 13 39 1.273240E-02 +Rdc_c13_e1 14 1 3.395291E-03 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 15 40 5.092958E-02 +Rdc_c2_e2 16 41 5.092958E-02 +Rdc_c3_e2 17 42 5.092958E-02 +Rdc_c4_e2 18 43 5.092958E-02 +Rdc_c5_e2 19 44 5.092958E-02 +Rdc_c6_e2 20 45 5.092958E-02 +Rdc_c7_e2 21 46 5.092958E-02 +Rdc_c8_e2 22 47 5.092958E-02 +Rdc_c9_e2 23 48 1.273240E-02 +Rdc_c10_e2 24 49 1.273240E-02 +Rdc_c11_e2 25 50 1.273240E-02 +Rdc_c12_e2 26 51 1.273240E-02 +Rdc_c13_e2 27 1 3.395291E-03 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 28 64 +Vmeas_domain_decomp_c2_e1 29 76 +Vmeas_domain_decomp_c3_e1 30 88 +Vmeas_domain_decomp_c4_e1 31 100 +Vmeas_domain_decomp_c5_e1 32 112 +Vmeas_domain_decomp_c6_e1 33 124 +Vmeas_domain_decomp_c7_e1 34 136 +Vmeas_domain_decomp_c8_e1 35 148 +Vmeas_domain_decomp_c9_e1 36 160 +Vmeas_domain_decomp_c10_e1 37 172 +Vmeas_domain_decomp_c11_e1 38 184 +Vmeas_domain_decomp_c12_e1 39 196 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 64 65 52 1 5.000000E-01 +E_domain_decomp_c1_dc2_e1 65 66 53 1 1.000000E+00 +E_domain_decomp_c1_dc3_e1 66 67 54 1 0.000000E+00 +E_domain_decomp_c1_dc4_e1 67 68 55 1 0.000000E+00 +E_domain_decomp_c1_dc5_e1 68 69 56 1 0.000000E+00 +E_domain_decomp_c1_dc6_e1 69 70 57 1 0.000000E+00 +E_domain_decomp_c1_dc7_e1 70 71 58 1 0.000000E+00 +E_domain_decomp_c1_dc8_e1 71 72 59 1 -0.000000E+00 +E_domain_decomp_c1_dc9_e1 72 73 60 1 1.000000E+00 +E_domain_decomp_c1_dc10_e1 73 74 61 1 0.000000E+00 +E_domain_decomp_c1_dc11_e1 74 75 62 1 0.000000E+00 +E_domain_decomp_c1_dc12_e1 75 1 63 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e1 76 77 52 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e1 77 78 53 1 1.000000E+00 +E_domain_decomp_c2_dc3_e1 78 79 54 1 0.000000E+00 +E_domain_decomp_c2_dc4_e1 79 80 55 1 0.000000E+00 +E_domain_decomp_c2_dc5_e1 80 81 56 1 0.000000E+00 +E_domain_decomp_c2_dc6_e1 81 82 57 1 0.000000E+00 +E_domain_decomp_c2_dc7_e1 82 83 58 1 0.000000E+00 +E_domain_decomp_c2_dc8_e1 83 84 59 1 -0.000000E+00 +E_domain_decomp_c2_dc9_e1 84 85 60 1 1.000000E+00 +E_domain_decomp_c2_dc10_e1 85 86 61 1 0.000000E+00 +E_domain_decomp_c2_dc11_e1 86 87 62 1 0.000000E+00 +E_domain_decomp_c2_dc12_e1 87 1 63 1 -0.000000E+00 +E_domain_decomp_c3_dc1_e1 88 89 52 1 0.000000E+00 +E_domain_decomp_c3_dc2_e1 89 90 53 1 0.000000E+00 +E_domain_decomp_c3_dc3_e1 90 91 54 1 5.000000E-01 +E_domain_decomp_c3_dc4_e1 91 92 55 1 1.000000E+00 +E_domain_decomp_c3_dc5_e1 92 93 56 1 0.000000E+00 +E_domain_decomp_c3_dc6_e1 93 94 57 1 0.000000E+00 +E_domain_decomp_c3_dc7_e1 94 95 58 1 0.000000E+00 +E_domain_decomp_c3_dc8_e1 95 96 59 1 0.000000E+00 +E_domain_decomp_c3_dc9_e1 96 97 60 1 -0.000000E+00 +E_domain_decomp_c3_dc10_e1 97 98 61 1 1.000000E+00 +E_domain_decomp_c3_dc11_e1 98 99 62 1 0.000000E+00 +E_domain_decomp_c3_dc12_e1 99 1 63 1 -0.000000E+00 +E_domain_decomp_c4_dc1_e1 100 101 52 1 0.000000E+00 +E_domain_decomp_c4_dc2_e1 101 102 53 1 0.000000E+00 +E_domain_decomp_c4_dc3_e1 102 103 54 1 -5.000000E-01 +E_domain_decomp_c4_dc4_e1 103 104 55 1 1.000000E+00 +E_domain_decomp_c4_dc5_e1 104 105 56 1 0.000000E+00 +E_domain_decomp_c4_dc6_e1 105 106 57 1 0.000000E+00 +E_domain_decomp_c4_dc7_e1 106 107 58 1 0.000000E+00 +E_domain_decomp_c4_dc8_e1 107 108 59 1 0.000000E+00 +E_domain_decomp_c4_dc9_e1 108 109 60 1 -0.000000E+00 +E_domain_decomp_c4_dc10_e1 109 110 61 1 1.000000E+00 +E_domain_decomp_c4_dc11_e1 110 111 62 1 0.000000E+00 +E_domain_decomp_c4_dc12_e1 111 1 63 1 -0.000000E+00 +E_domain_decomp_c5_dc1_e1 112 113 52 1 0.000000E+00 +E_domain_decomp_c5_dc2_e1 113 114 53 1 0.000000E+00 +E_domain_decomp_c5_dc3_e1 114 115 54 1 0.000000E+00 +E_domain_decomp_c5_dc4_e1 115 116 55 1 0.000000E+00 +E_domain_decomp_c5_dc5_e1 116 117 56 1 5.000000E-01 +E_domain_decomp_c5_dc6_e1 117 118 57 1 1.000000E+00 +E_domain_decomp_c5_dc7_e1 118 119 58 1 0.000000E+00 +E_domain_decomp_c5_dc8_e1 119 120 59 1 0.000000E+00 +E_domain_decomp_c5_dc9_e1 120 121 60 1 0.000000E+00 +E_domain_decomp_c5_dc10_e1 121 122 61 1 -0.000000E+00 +E_domain_decomp_c5_dc11_e1 122 123 62 1 1.000000E+00 +E_domain_decomp_c5_dc12_e1 123 1 63 1 -0.000000E+00 +E_domain_decomp_c6_dc1_e1 124 125 52 1 0.000000E+00 +E_domain_decomp_c6_dc2_e1 125 126 53 1 0.000000E+00 +E_domain_decomp_c6_dc3_e1 126 127 54 1 0.000000E+00 +E_domain_decomp_c6_dc4_e1 127 128 55 1 0.000000E+00 +E_domain_decomp_c6_dc5_e1 128 129 56 1 -5.000000E-01 +E_domain_decomp_c6_dc6_e1 129 130 57 1 1.000000E+00 +E_domain_decomp_c6_dc7_e1 130 131 58 1 0.000000E+00 +E_domain_decomp_c6_dc8_e1 131 132 59 1 0.000000E+00 +E_domain_decomp_c6_dc9_e1 132 133 60 1 0.000000E+00 +E_domain_decomp_c6_dc10_e1 133 134 61 1 -0.000000E+00 +E_domain_decomp_c6_dc11_e1 134 135 62 1 1.000000E+00 +E_domain_decomp_c6_dc12_e1 135 1 63 1 -0.000000E+00 +E_domain_decomp_c7_dc1_e1 136 137 52 1 0.000000E+00 +E_domain_decomp_c7_dc2_e1 137 138 53 1 0.000000E+00 +E_domain_decomp_c7_dc3_e1 138 139 54 1 0.000000E+00 +E_domain_decomp_c7_dc4_e1 139 140 55 1 0.000000E+00 +E_domain_decomp_c7_dc5_e1 140 141 56 1 0.000000E+00 +E_domain_decomp_c7_dc6_e1 141 142 57 1 0.000000E+00 +E_domain_decomp_c7_dc7_e1 142 143 58 1 5.000000E-01 +E_domain_decomp_c7_dc8_e1 143 144 59 1 1.000000E+00 +E_domain_decomp_c7_dc9_e1 144 145 60 1 0.000000E+00 +E_domain_decomp_c7_dc10_e1 145 146 61 1 0.000000E+00 +E_domain_decomp_c7_dc11_e1 146 147 62 1 -0.000000E+00 +E_domain_decomp_c7_dc12_e1 147 1 63 1 1.000000E+00 +E_domain_decomp_c8_dc1_e1 148 149 52 1 0.000000E+00 +E_domain_decomp_c8_dc2_e1 149 150 53 1 0.000000E+00 +E_domain_decomp_c8_dc3_e1 150 151 54 1 0.000000E+00 +E_domain_decomp_c8_dc4_e1 151 152 55 1 0.000000E+00 +E_domain_decomp_c8_dc5_e1 152 153 56 1 0.000000E+00 +E_domain_decomp_c8_dc6_e1 153 154 57 1 0.000000E+00 +E_domain_decomp_c8_dc7_e1 154 155 58 1 -5.000000E-01 +E_domain_decomp_c8_dc8_e1 155 156 59 1 1.000000E+00 +E_domain_decomp_c8_dc9_e1 156 157 60 1 0.000000E+00 +E_domain_decomp_c8_dc10_e1 157 158 61 1 0.000000E+00 +E_domain_decomp_c8_dc11_e1 158 159 62 1 -0.000000E+00 +E_domain_decomp_c8_dc12_e1 159 1 63 1 1.000000E+00 +E_domain_decomp_c9_dc1_e1 160 161 52 1 0.000000E+00 +E_domain_decomp_c9_dc2_e1 161 162 53 1 0.000000E+00 +E_domain_decomp_c9_dc3_e1 162 163 54 1 0.000000E+00 +E_domain_decomp_c9_dc4_e1 163 164 55 1 0.000000E+00 +E_domain_decomp_c9_dc5_e1 164 165 56 1 0.000000E+00 +E_domain_decomp_c9_dc6_e1 165 166 57 1 0.000000E+00 +E_domain_decomp_c9_dc7_e1 166 167 58 1 0.000000E+00 +E_domain_decomp_c9_dc8_e1 167 168 59 1 -0.000000E+00 +E_domain_decomp_c9_dc9_e1 168 169 60 1 1.000000E+00 +E_domain_decomp_c9_dc10_e1 169 170 61 1 0.000000E+00 +E_domain_decomp_c9_dc11_e1 170 171 62 1 0.000000E+00 +E_domain_decomp_c9_dc12_e1 171 1 63 1 -0.000000E+00 +E_domain_decomp_c10_dc1_e1 172 173 52 1 0.000000E+00 +E_domain_decomp_c10_dc2_e1 173 174 53 1 0.000000E+00 +E_domain_decomp_c10_dc3_e1 174 175 54 1 0.000000E+00 +E_domain_decomp_c10_dc4_e1 175 176 55 1 0.000000E+00 +E_domain_decomp_c10_dc5_e1 176 177 56 1 0.000000E+00 +E_domain_decomp_c10_dc6_e1 177 178 57 1 0.000000E+00 +E_domain_decomp_c10_dc7_e1 178 179 58 1 0.000000E+00 +E_domain_decomp_c10_dc8_e1 179 180 59 1 0.000000E+00 +E_domain_decomp_c10_dc9_e1 180 181 60 1 -0.000000E+00 +E_domain_decomp_c10_dc10_e1 181 182 61 1 1.000000E+00 +E_domain_decomp_c10_dc11_e1 182 183 62 1 0.000000E+00 +E_domain_decomp_c10_dc12_e1 183 1 63 1 -0.000000E+00 +E_domain_decomp_c11_dc1_e1 184 185 52 1 0.000000E+00 +E_domain_decomp_c11_dc2_e1 185 186 53 1 0.000000E+00 +E_domain_decomp_c11_dc3_e1 186 187 54 1 0.000000E+00 +E_domain_decomp_c11_dc4_e1 187 188 55 1 0.000000E+00 +E_domain_decomp_c11_dc5_e1 188 189 56 1 0.000000E+00 +E_domain_decomp_c11_dc6_e1 189 190 57 1 0.000000E+00 +E_domain_decomp_c11_dc7_e1 190 191 58 1 0.000000E+00 +E_domain_decomp_c11_dc8_e1 191 192 59 1 0.000000E+00 +E_domain_decomp_c11_dc9_e1 192 193 60 1 0.000000E+00 +E_domain_decomp_c11_dc10_e1 193 194 61 1 -0.000000E+00 +E_domain_decomp_c11_dc11_e1 194 195 62 1 1.000000E+00 +E_domain_decomp_c11_dc12_e1 195 1 63 1 -0.000000E+00 +E_domain_decomp_c12_dc1_e1 196 197 52 1 0.000000E+00 +E_domain_decomp_c12_dc2_e1 197 198 53 1 0.000000E+00 +E_domain_decomp_c12_dc3_e1 198 199 54 1 0.000000E+00 +E_domain_decomp_c12_dc4_e1 199 200 55 1 0.000000E+00 +E_domain_decomp_c12_dc5_e1 200 201 56 1 0.000000E+00 +E_domain_decomp_c12_dc6_e1 201 202 57 1 0.000000E+00 +E_domain_decomp_c12_dc7_e1 202 203 58 1 0.000000E+00 +E_domain_decomp_c12_dc8_e1 203 204 59 1 0.000000E+00 +E_domain_decomp_c12_dc9_e1 204 205 60 1 0.000000E+00 +E_domain_decomp_c12_dc10_e1 205 206 61 1 0.000000E+00 +E_domain_decomp_c12_dc11_e1 206 207 62 1 -0.000000E+00 +E_domain_decomp_c12_dc12_e1 207 1 63 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 52 Vmeas_domain_decomp_c1_e1 5.000000E-01 +F_domain_decomp_c2_dc1_e1 1 52 Vmeas_domain_decomp_c2_e1 -5.000000E-01 +F_domain_decomp_c3_dc1_e1 1 52 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc1_e1 1 52 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc1_e1 1 52 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc1_e1 1 52 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc1_e1 1 52 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc1_e1 1 52 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc1_e1 1 52 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc1_e1 1 52 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc1_e1 1 52 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc1_e1 1 52 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 53 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 53 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c3_dc2_e1 1 53 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc2_e1 1 53 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc2_e1 1 53 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc2_e1 1 53 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc2_e1 1 53 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc2_e1 1 53 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc2_e1 1 53 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc2_e1 1 53 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc2_e1 1 53 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc2_e1 1 53 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc3_e1 1 54 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc3_e1 1 54 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc3_e1 1 54 Vmeas_domain_decomp_c3_e1 5.000000E-01 +F_domain_decomp_c4_dc3_e1 1 54 Vmeas_domain_decomp_c4_e1 -5.000000E-01 +F_domain_decomp_c5_dc3_e1 1 54 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc3_e1 1 54 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc3_e1 1 54 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc3_e1 1 54 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc3_e1 1 54 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc3_e1 1 54 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc3_e1 1 54 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc3_e1 1 54 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc4_e1 1 55 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc4_e1 1 55 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc4_e1 1 55 Vmeas_domain_decomp_c3_e1 1.000000E+00 +F_domain_decomp_c4_dc4_e1 1 55 Vmeas_domain_decomp_c4_e1 1.000000E+00 +F_domain_decomp_c5_dc4_e1 1 55 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc4_e1 1 55 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc4_e1 1 55 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc4_e1 1 55 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc4_e1 1 55 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc4_e1 1 55 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc4_e1 1 55 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc4_e1 1 55 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc5_e1 1 56 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc5_e1 1 56 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc5_e1 1 56 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc5_e1 1 56 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc5_e1 1 56 Vmeas_domain_decomp_c5_e1 5.000000E-01 +F_domain_decomp_c6_dc5_e1 1 56 Vmeas_domain_decomp_c6_e1 -5.000000E-01 +F_domain_decomp_c7_dc5_e1 1 56 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc5_e1 1 56 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc5_e1 1 56 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc5_e1 1 56 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc5_e1 1 56 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc5_e1 1 56 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc6_e1 1 57 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc6_e1 1 57 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc6_e1 1 57 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc6_e1 1 57 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc6_e1 1 57 Vmeas_domain_decomp_c5_e1 1.000000E+00 +F_domain_decomp_c6_dc6_e1 1 57 Vmeas_domain_decomp_c6_e1 1.000000E+00 +F_domain_decomp_c7_dc6_e1 1 57 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc6_e1 1 57 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc6_e1 1 57 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc6_e1 1 57 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc6_e1 1 57 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc6_e1 1 57 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc7_e1 1 58 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc7_e1 1 58 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc7_e1 1 58 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc7_e1 1 58 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc7_e1 1 58 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc7_e1 1 58 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc7_e1 1 58 Vmeas_domain_decomp_c7_e1 5.000000E-01 +F_domain_decomp_c8_dc7_e1 1 58 Vmeas_domain_decomp_c8_e1 -5.000000E-01 +F_domain_decomp_c9_dc7_e1 1 58 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc7_e1 1 58 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc7_e1 1 58 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc7_e1 1 58 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc8_e1 1 59 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc8_e1 1 59 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc8_e1 1 59 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc8_e1 1 59 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc8_e1 1 59 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc8_e1 1 59 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc8_e1 1 59 Vmeas_domain_decomp_c7_e1 1.000000E+00 +F_domain_decomp_c8_dc8_e1 1 59 Vmeas_domain_decomp_c8_e1 1.000000E+00 +F_domain_decomp_c9_dc8_e1 1 59 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc8_e1 1 59 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc8_e1 1 59 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc8_e1 1 59 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc9_e1 1 60 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc9_e1 1 60 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c3_dc9_e1 1 60 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc9_e1 1 60 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc9_e1 1 60 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc9_e1 1 60 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc9_e1 1 60 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc9_e1 1 60 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc9_e1 1 60 Vmeas_domain_decomp_c9_e1 1.000000E+00 +F_domain_decomp_c10_dc9_e1 1 60 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc9_e1 1 60 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc9_e1 1 60 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc10_e1 1 61 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc10_e1 1 61 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc10_e1 1 61 Vmeas_domain_decomp_c3_e1 1.000000E+00 +F_domain_decomp_c4_dc10_e1 1 61 Vmeas_domain_decomp_c4_e1 1.000000E+00 +F_domain_decomp_c5_dc10_e1 1 61 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc10_e1 1 61 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc10_e1 1 61 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc10_e1 1 61 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc10_e1 1 61 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc10_e1 1 61 Vmeas_domain_decomp_c10_e1 1.000000E+00 +F_domain_decomp_c11_dc10_e1 1 61 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc10_e1 1 61 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc11_e1 1 62 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc11_e1 1 62 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc11_e1 1 62 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc11_e1 1 62 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc11_e1 1 62 Vmeas_domain_decomp_c5_e1 1.000000E+00 +F_domain_decomp_c6_dc11_e1 1 62 Vmeas_domain_decomp_c6_e1 1.000000E+00 +F_domain_decomp_c7_dc11_e1 1 62 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc11_e1 1 62 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc11_e1 1 62 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc11_e1 1 62 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc11_e1 1 62 Vmeas_domain_decomp_c11_e1 1.000000E+00 +F_domain_decomp_c12_dc11_e1 1 62 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc12_e1 1 63 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc12_e1 1 63 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc12_e1 1 63 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc12_e1 1 63 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc12_e1 1 63 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc12_e1 1 63 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc12_e1 1 63 Vmeas_domain_decomp_c7_e1 1.000000E+00 +F_domain_decomp_c8_dc12_e1 1 63 Vmeas_domain_decomp_c8_e1 1.000000E+00 +F_domain_decomp_c9_dc12_e1 1 63 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc12_e1 1 63 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc12_e1 1 63 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc12_e1 1 63 Vmeas_domain_decomp_c12_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 40 220 +Vmeas_domain_decomp_c2_e2 41 232 +Vmeas_domain_decomp_c3_e2 42 244 +Vmeas_domain_decomp_c4_e2 43 256 +Vmeas_domain_decomp_c5_e2 44 268 +Vmeas_domain_decomp_c6_e2 45 280 +Vmeas_domain_decomp_c7_e2 46 292 +Vmeas_domain_decomp_c8_e2 47 304 +Vmeas_domain_decomp_c9_e2 48 316 +Vmeas_domain_decomp_c10_e2 49 328 +Vmeas_domain_decomp_c11_e2 50 340 +Vmeas_domain_decomp_c12_e2 51 352 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 220 221 208 1 5.000000E-01 +E_domain_decomp_c1_dc2_e2 221 222 209 1 1.000000E+00 +E_domain_decomp_c1_dc3_e2 222 223 210 1 0.000000E+00 +E_domain_decomp_c1_dc4_e2 223 224 211 1 0.000000E+00 +E_domain_decomp_c1_dc5_e2 224 225 212 1 0.000000E+00 +E_domain_decomp_c1_dc6_e2 225 226 213 1 0.000000E+00 +E_domain_decomp_c1_dc7_e2 226 227 214 1 0.000000E+00 +E_domain_decomp_c1_dc8_e2 227 228 215 1 -0.000000E+00 +E_domain_decomp_c1_dc9_e2 228 229 216 1 1.000000E+00 +E_domain_decomp_c1_dc10_e2 229 230 217 1 0.000000E+00 +E_domain_decomp_c1_dc11_e2 230 231 218 1 0.000000E+00 +E_domain_decomp_c1_dc12_e2 231 1 219 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e2 232 233 208 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e2 233 234 209 1 1.000000E+00 +E_domain_decomp_c2_dc3_e2 234 235 210 1 0.000000E+00 +E_domain_decomp_c2_dc4_e2 235 236 211 1 0.000000E+00 +E_domain_decomp_c2_dc5_e2 236 237 212 1 0.000000E+00 +E_domain_decomp_c2_dc6_e2 237 238 213 1 0.000000E+00 +E_domain_decomp_c2_dc7_e2 238 239 214 1 0.000000E+00 +E_domain_decomp_c2_dc8_e2 239 240 215 1 -0.000000E+00 +E_domain_decomp_c2_dc9_e2 240 241 216 1 1.000000E+00 +E_domain_decomp_c2_dc10_e2 241 242 217 1 0.000000E+00 +E_domain_decomp_c2_dc11_e2 242 243 218 1 0.000000E+00 +E_domain_decomp_c2_dc12_e2 243 1 219 1 -0.000000E+00 +E_domain_decomp_c3_dc1_e2 244 245 208 1 0.000000E+00 +E_domain_decomp_c3_dc2_e2 245 246 209 1 0.000000E+00 +E_domain_decomp_c3_dc3_e2 246 247 210 1 5.000000E-01 +E_domain_decomp_c3_dc4_e2 247 248 211 1 1.000000E+00 +E_domain_decomp_c3_dc5_e2 248 249 212 1 0.000000E+00 +E_domain_decomp_c3_dc6_e2 249 250 213 1 0.000000E+00 +E_domain_decomp_c3_dc7_e2 250 251 214 1 0.000000E+00 +E_domain_decomp_c3_dc8_e2 251 252 215 1 0.000000E+00 +E_domain_decomp_c3_dc9_e2 252 253 216 1 -0.000000E+00 +E_domain_decomp_c3_dc10_e2 253 254 217 1 1.000000E+00 +E_domain_decomp_c3_dc11_e2 254 255 218 1 0.000000E+00 +E_domain_decomp_c3_dc12_e2 255 1 219 1 -0.000000E+00 +E_domain_decomp_c4_dc1_e2 256 257 208 1 0.000000E+00 +E_domain_decomp_c4_dc2_e2 257 258 209 1 0.000000E+00 +E_domain_decomp_c4_dc3_e2 258 259 210 1 -5.000000E-01 +E_domain_decomp_c4_dc4_e2 259 260 211 1 1.000000E+00 +E_domain_decomp_c4_dc5_e2 260 261 212 1 0.000000E+00 +E_domain_decomp_c4_dc6_e2 261 262 213 1 0.000000E+00 +E_domain_decomp_c4_dc7_e2 262 263 214 1 0.000000E+00 +E_domain_decomp_c4_dc8_e2 263 264 215 1 0.000000E+00 +E_domain_decomp_c4_dc9_e2 264 265 216 1 -0.000000E+00 +E_domain_decomp_c4_dc10_e2 265 266 217 1 1.000000E+00 +E_domain_decomp_c4_dc11_e2 266 267 218 1 0.000000E+00 +E_domain_decomp_c4_dc12_e2 267 1 219 1 -0.000000E+00 +E_domain_decomp_c5_dc1_e2 268 269 208 1 0.000000E+00 +E_domain_decomp_c5_dc2_e2 269 270 209 1 0.000000E+00 +E_domain_decomp_c5_dc3_e2 270 271 210 1 0.000000E+00 +E_domain_decomp_c5_dc4_e2 271 272 211 1 0.000000E+00 +E_domain_decomp_c5_dc5_e2 272 273 212 1 5.000000E-01 +E_domain_decomp_c5_dc6_e2 273 274 213 1 1.000000E+00 +E_domain_decomp_c5_dc7_e2 274 275 214 1 0.000000E+00 +E_domain_decomp_c5_dc8_e2 275 276 215 1 0.000000E+00 +E_domain_decomp_c5_dc9_e2 276 277 216 1 0.000000E+00 +E_domain_decomp_c5_dc10_e2 277 278 217 1 -0.000000E+00 +E_domain_decomp_c5_dc11_e2 278 279 218 1 1.000000E+00 +E_domain_decomp_c5_dc12_e2 279 1 219 1 -0.000000E+00 +E_domain_decomp_c6_dc1_e2 280 281 208 1 0.000000E+00 +E_domain_decomp_c6_dc2_e2 281 282 209 1 0.000000E+00 +E_domain_decomp_c6_dc3_e2 282 283 210 1 0.000000E+00 +E_domain_decomp_c6_dc4_e2 283 284 211 1 0.000000E+00 +E_domain_decomp_c6_dc5_e2 284 285 212 1 -5.000000E-01 +E_domain_decomp_c6_dc6_e2 285 286 213 1 1.000000E+00 +E_domain_decomp_c6_dc7_e2 286 287 214 1 0.000000E+00 +E_domain_decomp_c6_dc8_e2 287 288 215 1 0.000000E+00 +E_domain_decomp_c6_dc9_e2 288 289 216 1 0.000000E+00 +E_domain_decomp_c6_dc10_e2 289 290 217 1 -0.000000E+00 +E_domain_decomp_c6_dc11_e2 290 291 218 1 1.000000E+00 +E_domain_decomp_c6_dc12_e2 291 1 219 1 -0.000000E+00 +E_domain_decomp_c7_dc1_e2 292 293 208 1 0.000000E+00 +E_domain_decomp_c7_dc2_e2 293 294 209 1 0.000000E+00 +E_domain_decomp_c7_dc3_e2 294 295 210 1 0.000000E+00 +E_domain_decomp_c7_dc4_e2 295 296 211 1 0.000000E+00 +E_domain_decomp_c7_dc5_e2 296 297 212 1 0.000000E+00 +E_domain_decomp_c7_dc6_e2 297 298 213 1 0.000000E+00 +E_domain_decomp_c7_dc7_e2 298 299 214 1 5.000000E-01 +E_domain_decomp_c7_dc8_e2 299 300 215 1 1.000000E+00 +E_domain_decomp_c7_dc9_e2 300 301 216 1 0.000000E+00 +E_domain_decomp_c7_dc10_e2 301 302 217 1 0.000000E+00 +E_domain_decomp_c7_dc11_e2 302 303 218 1 -0.000000E+00 +E_domain_decomp_c7_dc12_e2 303 1 219 1 1.000000E+00 +E_domain_decomp_c8_dc1_e2 304 305 208 1 0.000000E+00 +E_domain_decomp_c8_dc2_e2 305 306 209 1 0.000000E+00 +E_domain_decomp_c8_dc3_e2 306 307 210 1 0.000000E+00 +E_domain_decomp_c8_dc4_e2 307 308 211 1 0.000000E+00 +E_domain_decomp_c8_dc5_e2 308 309 212 1 0.000000E+00 +E_domain_decomp_c8_dc6_e2 309 310 213 1 0.000000E+00 +E_domain_decomp_c8_dc7_e2 310 311 214 1 -5.000000E-01 +E_domain_decomp_c8_dc8_e2 311 312 215 1 1.000000E+00 +E_domain_decomp_c8_dc9_e2 312 313 216 1 0.000000E+00 +E_domain_decomp_c8_dc10_e2 313 314 217 1 0.000000E+00 +E_domain_decomp_c8_dc11_e2 314 315 218 1 -0.000000E+00 +E_domain_decomp_c8_dc12_e2 315 1 219 1 1.000000E+00 +E_domain_decomp_c9_dc1_e2 316 317 208 1 0.000000E+00 +E_domain_decomp_c9_dc2_e2 317 318 209 1 0.000000E+00 +E_domain_decomp_c9_dc3_e2 318 319 210 1 0.000000E+00 +E_domain_decomp_c9_dc4_e2 319 320 211 1 0.000000E+00 +E_domain_decomp_c9_dc5_e2 320 321 212 1 0.000000E+00 +E_domain_decomp_c9_dc6_e2 321 322 213 1 0.000000E+00 +E_domain_decomp_c9_dc7_e2 322 323 214 1 0.000000E+00 +E_domain_decomp_c9_dc8_e2 323 324 215 1 -0.000000E+00 +E_domain_decomp_c9_dc9_e2 324 325 216 1 1.000000E+00 +E_domain_decomp_c9_dc10_e2 325 326 217 1 0.000000E+00 +E_domain_decomp_c9_dc11_e2 326 327 218 1 0.000000E+00 +E_domain_decomp_c9_dc12_e2 327 1 219 1 -0.000000E+00 +E_domain_decomp_c10_dc1_e2 328 329 208 1 0.000000E+00 +E_domain_decomp_c10_dc2_e2 329 330 209 1 0.000000E+00 +E_domain_decomp_c10_dc3_e2 330 331 210 1 0.000000E+00 +E_domain_decomp_c10_dc4_e2 331 332 211 1 0.000000E+00 +E_domain_decomp_c10_dc5_e2 332 333 212 1 0.000000E+00 +E_domain_decomp_c10_dc6_e2 333 334 213 1 0.000000E+00 +E_domain_decomp_c10_dc7_e2 334 335 214 1 0.000000E+00 +E_domain_decomp_c10_dc8_e2 335 336 215 1 0.000000E+00 +E_domain_decomp_c10_dc9_e2 336 337 216 1 -0.000000E+00 +E_domain_decomp_c10_dc10_e2 337 338 217 1 1.000000E+00 +E_domain_decomp_c10_dc11_e2 338 339 218 1 0.000000E+00 +E_domain_decomp_c10_dc12_e2 339 1 219 1 -0.000000E+00 +E_domain_decomp_c11_dc1_e2 340 341 208 1 0.000000E+00 +E_domain_decomp_c11_dc2_e2 341 342 209 1 0.000000E+00 +E_domain_decomp_c11_dc3_e2 342 343 210 1 0.000000E+00 +E_domain_decomp_c11_dc4_e2 343 344 211 1 0.000000E+00 +E_domain_decomp_c11_dc5_e2 344 345 212 1 0.000000E+00 +E_domain_decomp_c11_dc6_e2 345 346 213 1 0.000000E+00 +E_domain_decomp_c11_dc7_e2 346 347 214 1 0.000000E+00 +E_domain_decomp_c11_dc8_e2 347 348 215 1 0.000000E+00 +E_domain_decomp_c11_dc9_e2 348 349 216 1 0.000000E+00 +E_domain_decomp_c11_dc10_e2 349 350 217 1 -0.000000E+00 +E_domain_decomp_c11_dc11_e2 350 351 218 1 1.000000E+00 +E_domain_decomp_c11_dc12_e2 351 1 219 1 -0.000000E+00 +E_domain_decomp_c12_dc1_e2 352 353 208 1 0.000000E+00 +E_domain_decomp_c12_dc2_e2 353 354 209 1 0.000000E+00 +E_domain_decomp_c12_dc3_e2 354 355 210 1 0.000000E+00 +E_domain_decomp_c12_dc4_e2 355 356 211 1 0.000000E+00 +E_domain_decomp_c12_dc5_e2 356 357 212 1 0.000000E+00 +E_domain_decomp_c12_dc6_e2 357 358 213 1 0.000000E+00 +E_domain_decomp_c12_dc7_e2 358 359 214 1 0.000000E+00 +E_domain_decomp_c12_dc8_e2 359 360 215 1 0.000000E+00 +E_domain_decomp_c12_dc9_e2 360 361 216 1 0.000000E+00 +E_domain_decomp_c12_dc10_e2 361 362 217 1 0.000000E+00 +E_domain_decomp_c12_dc11_e2 362 363 218 1 -0.000000E+00 +E_domain_decomp_c12_dc12_e2 363 1 219 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 208 Vmeas_domain_decomp_c1_e2 5.000000E-01 +F_domain_decomp_c2_dc1_e2 1 208 Vmeas_domain_decomp_c2_e2 -5.000000E-01 +F_domain_decomp_c3_dc1_e2 1 208 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc1_e2 1 208 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc1_e2 1 208 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc1_e2 1 208 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc1_e2 1 208 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc1_e2 1 208 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc1_e2 1 208 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc1_e2 1 208 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc1_e2 1 208 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc1_e2 1 208 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 209 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 209 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c3_dc2_e2 1 209 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc2_e2 1 209 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc2_e2 1 209 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc2_e2 1 209 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc2_e2 1 209 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc2_e2 1 209 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc2_e2 1 209 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc2_e2 1 209 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc2_e2 1 209 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc2_e2 1 209 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc3_e2 1 210 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc3_e2 1 210 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc3_e2 1 210 Vmeas_domain_decomp_c3_e2 5.000000E-01 +F_domain_decomp_c4_dc3_e2 1 210 Vmeas_domain_decomp_c4_e2 -5.000000E-01 +F_domain_decomp_c5_dc3_e2 1 210 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc3_e2 1 210 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc3_e2 1 210 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc3_e2 1 210 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc3_e2 1 210 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc3_e2 1 210 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc3_e2 1 210 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc3_e2 1 210 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc4_e2 1 211 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc4_e2 1 211 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc4_e2 1 211 Vmeas_domain_decomp_c3_e2 1.000000E+00 +F_domain_decomp_c4_dc4_e2 1 211 Vmeas_domain_decomp_c4_e2 1.000000E+00 +F_domain_decomp_c5_dc4_e2 1 211 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc4_e2 1 211 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc4_e2 1 211 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc4_e2 1 211 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc4_e2 1 211 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc4_e2 1 211 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc4_e2 1 211 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc4_e2 1 211 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc5_e2 1 212 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc5_e2 1 212 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc5_e2 1 212 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc5_e2 1 212 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc5_e2 1 212 Vmeas_domain_decomp_c5_e2 5.000000E-01 +F_domain_decomp_c6_dc5_e2 1 212 Vmeas_domain_decomp_c6_e2 -5.000000E-01 +F_domain_decomp_c7_dc5_e2 1 212 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc5_e2 1 212 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc5_e2 1 212 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc5_e2 1 212 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc5_e2 1 212 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc5_e2 1 212 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc6_e2 1 213 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc6_e2 1 213 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc6_e2 1 213 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc6_e2 1 213 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc6_e2 1 213 Vmeas_domain_decomp_c5_e2 1.000000E+00 +F_domain_decomp_c6_dc6_e2 1 213 Vmeas_domain_decomp_c6_e2 1.000000E+00 +F_domain_decomp_c7_dc6_e2 1 213 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc6_e2 1 213 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc6_e2 1 213 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc6_e2 1 213 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc6_e2 1 213 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc6_e2 1 213 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc7_e2 1 214 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc7_e2 1 214 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc7_e2 1 214 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc7_e2 1 214 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc7_e2 1 214 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc7_e2 1 214 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc7_e2 1 214 Vmeas_domain_decomp_c7_e2 5.000000E-01 +F_domain_decomp_c8_dc7_e2 1 214 Vmeas_domain_decomp_c8_e2 -5.000000E-01 +F_domain_decomp_c9_dc7_e2 1 214 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc7_e2 1 214 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc7_e2 1 214 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc7_e2 1 214 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc8_e2 1 215 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc8_e2 1 215 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc8_e2 1 215 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc8_e2 1 215 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc8_e2 1 215 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc8_e2 1 215 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc8_e2 1 215 Vmeas_domain_decomp_c7_e2 1.000000E+00 +F_domain_decomp_c8_dc8_e2 1 215 Vmeas_domain_decomp_c8_e2 1.000000E+00 +F_domain_decomp_c9_dc8_e2 1 215 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc8_e2 1 215 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc8_e2 1 215 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc8_e2 1 215 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc9_e2 1 216 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc9_e2 1 216 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c3_dc9_e2 1 216 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc9_e2 1 216 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc9_e2 1 216 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc9_e2 1 216 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc9_e2 1 216 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc9_e2 1 216 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc9_e2 1 216 Vmeas_domain_decomp_c9_e2 1.000000E+00 +F_domain_decomp_c10_dc9_e2 1 216 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc9_e2 1 216 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc9_e2 1 216 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc10_e2 1 217 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc10_e2 1 217 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc10_e2 1 217 Vmeas_domain_decomp_c3_e2 1.000000E+00 +F_domain_decomp_c4_dc10_e2 1 217 Vmeas_domain_decomp_c4_e2 1.000000E+00 +F_domain_decomp_c5_dc10_e2 1 217 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc10_e2 1 217 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc10_e2 1 217 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc10_e2 1 217 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc10_e2 1 217 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc10_e2 1 217 Vmeas_domain_decomp_c10_e2 1.000000E+00 +F_domain_decomp_c11_dc10_e2 1 217 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc10_e2 1 217 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc11_e2 1 218 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc11_e2 1 218 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc11_e2 1 218 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc11_e2 1 218 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc11_e2 1 218 Vmeas_domain_decomp_c5_e2 1.000000E+00 +F_domain_decomp_c6_dc11_e2 1 218 Vmeas_domain_decomp_c6_e2 1.000000E+00 +F_domain_decomp_c7_dc11_e2 1 218 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc11_e2 1 218 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc11_e2 1 218 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc11_e2 1 218 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc11_e2 1 218 Vmeas_domain_decomp_c11_e2 1.000000E+00 +F_domain_decomp_c12_dc11_e2 1 218 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc12_e2 1 219 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc12_e2 1 219 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc12_e2 1 219 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc12_e2 1 219 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc12_e2 1 219 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc12_e2 1 219 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc12_e2 1 219 Vmeas_domain_decomp_c7_e2 1.000000E+00 +F_domain_decomp_c8_dc12_e2 1 219 Vmeas_domain_decomp_c8_e2 1.000000E+00 +F_domain_decomp_c9_dc12_e2 1 219 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc12_e2 1 219 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc12_e2 1 219 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc12_e2 1 219 Vmeas_domain_decomp_c12_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 52 365 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 365 1 364 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 364 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 208 367 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 367 1 366 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 366 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 364 368 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 366 369 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 368 1 370 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 369 1 371 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 371 1 372 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 370 1 373 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 371 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 370 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 372 374 364 1 2.000000E+00 +E_m_pz_d1_m1_e2 374 1 368 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 373 375 366 1 2.000000E+00 +E_m_mz_d1_m1_e2 375 1 369 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 53 377 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 377 1 376 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 376 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 209 379 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 379 1 378 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 378 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 376 380 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 378 381 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 380 1 382 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 381 1 383 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 383 1 384 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 382 1 385 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 383 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 382 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 384 386 376 1 2.000000E+00 +E_m_pz_d2_m1_e2 386 1 380 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 385 387 378 1 2.000000E+00 +E_m_mz_d2_m1_e2 387 1 381 1 -1.000000E+00 +* +* DOMAIN 3 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d3_c1_e1 54 389 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d3_c1_m1_e1 389 1 388 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d3_c1_m1_e1 1 388 Vmeas_mode_decomp_d3_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d3_c1_e2 210 391 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d3_c1_m1_e2 391 1 390 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d3_c1_m1_e2 1 390 Vmeas_mode_decomp_d3_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d3_m1_e1 388 392 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d3_m1_e2 390 393 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d3_m1_e1 392 1 394 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d3_m1_e2 393 1 395 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d3_m1_e1 395 1 396 1 LTRA_T_pz_d3_m1_e1 +.MODEL LTRA_T_pz_d3_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d3_m1_e2 394 1 397 1 LTRA_T_mz_d3_m1_e2 +.MODEL LTRA_T_mz_d3_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d3_m1_e1 395 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d3_m1_e2 394 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d3_m1_e1 396 398 388 1 2.000000E+00 +E_m_pz_d3_m1_e2 398 1 392 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d3_m1_e1 397 399 390 1 2.000000E+00 +E_m_mz_d3_m1_e2 399 1 393 1 -1.000000E+00 +* +* DOMAIN 4 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d4_c1_e1 55 401 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d4_c1_m1_e1 401 1 400 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d4_c1_m1_e1 1 400 Vmeas_mode_decomp_d4_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d4_c1_e2 211 403 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d4_c1_m1_e2 403 1 402 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d4_c1_m1_e2 1 402 Vmeas_mode_decomp_d4_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d4_m1_e1 400 404 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d4_m1_e2 402 405 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d4_m1_e1 404 1 406 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d4_m1_e2 405 1 407 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d4_m1_e1 407 1 408 1 LTRA_T_pz_d4_m1_e1 +.MODEL LTRA_T_pz_d4_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d4_m1_e2 406 1 409 1 LTRA_T_mz_d4_m1_e2 +.MODEL LTRA_T_mz_d4_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d4_m1_e1 407 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d4_m1_e2 406 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d4_m1_e1 408 410 400 1 2.000000E+00 +E_m_pz_d4_m1_e2 410 1 404 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d4_m1_e1 409 411 402 1 2.000000E+00 +E_m_mz_d4_m1_e2 411 1 405 1 -1.000000E+00 +* +* DOMAIN 5 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d5_c1_e1 56 413 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d5_c1_m1_e1 413 1 412 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d5_c1_m1_e1 1 412 Vmeas_mode_decomp_d5_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d5_c1_e2 212 415 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d5_c1_m1_e2 415 1 414 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d5_c1_m1_e2 1 414 Vmeas_mode_decomp_d5_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d5_m1_e1 412 416 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d5_m1_e2 414 417 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d5_m1_e1 416 1 418 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d5_m1_e2 417 1 419 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d5_m1_e1 419 1 420 1 LTRA_T_pz_d5_m1_e1 +.MODEL LTRA_T_pz_d5_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d5_m1_e2 418 1 421 1 LTRA_T_mz_d5_m1_e2 +.MODEL LTRA_T_mz_d5_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d5_m1_e1 419 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d5_m1_e2 418 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d5_m1_e1 420 422 412 1 2.000000E+00 +E_m_pz_d5_m1_e2 422 1 416 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d5_m1_e1 421 423 414 1 2.000000E+00 +E_m_mz_d5_m1_e2 423 1 417 1 -1.000000E+00 +* +* DOMAIN 6 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d6_c1_e1 57 425 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d6_c1_m1_e1 425 1 424 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d6_c1_m1_e1 1 424 Vmeas_mode_decomp_d6_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d6_c1_e2 213 427 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d6_c1_m1_e2 427 1 426 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d6_c1_m1_e2 1 426 Vmeas_mode_decomp_d6_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d6_m1_e1 424 428 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d6_m1_e2 426 429 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d6_m1_e1 428 1 430 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d6_m1_e2 429 1 431 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d6_m1_e1 431 1 432 1 LTRA_T_pz_d6_m1_e1 +.MODEL LTRA_T_pz_d6_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d6_m1_e2 430 1 433 1 LTRA_T_mz_d6_m1_e2 +.MODEL LTRA_T_mz_d6_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d6_m1_e1 431 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d6_m1_e2 430 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d6_m1_e1 432 434 424 1 2.000000E+00 +E_m_pz_d6_m1_e2 434 1 428 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d6_m1_e1 433 435 426 1 2.000000E+00 +E_m_mz_d6_m1_e2 435 1 429 1 -1.000000E+00 +* +* DOMAIN 7 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d7_c1_e1 58 437 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d7_c1_m1_e1 437 1 436 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d7_c1_m1_e1 1 436 Vmeas_mode_decomp_d7_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d7_c1_e2 214 439 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d7_c1_m1_e2 439 1 438 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d7_c1_m1_e2 1 438 Vmeas_mode_decomp_d7_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d7_m1_e1 436 440 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d7_m1_e2 438 441 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d7_m1_e1 440 1 442 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d7_m1_e2 441 1 443 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d7_m1_e1 443 1 444 1 LTRA_T_pz_d7_m1_e1 +.MODEL LTRA_T_pz_d7_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d7_m1_e2 442 1 445 1 LTRA_T_mz_d7_m1_e2 +.MODEL LTRA_T_mz_d7_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d7_m1_e1 443 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d7_m1_e2 442 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d7_m1_e1 444 446 436 1 2.000000E+00 +E_m_pz_d7_m1_e2 446 1 440 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d7_m1_e1 445 447 438 1 2.000000E+00 +E_m_mz_d7_m1_e2 447 1 441 1 -1.000000E+00 +* +* DOMAIN 8 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d8_c1_e1 59 449 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d8_c1_m1_e1 449 1 448 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d8_c1_m1_e1 1 448 Vmeas_mode_decomp_d8_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d8_c1_e2 215 451 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d8_c1_m1_e2 451 1 450 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d8_c1_m1_e2 1 450 Vmeas_mode_decomp_d8_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d8_m1_e1 448 452 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d8_m1_e2 450 453 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d8_m1_e1 452 1 454 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d8_m1_e2 453 1 455 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d8_m1_e1 455 1 456 1 LTRA_T_pz_d8_m1_e1 +.MODEL LTRA_T_pz_d8_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d8_m1_e2 454 1 457 1 LTRA_T_mz_d8_m1_e2 +.MODEL LTRA_T_mz_d8_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d8_m1_e1 455 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d8_m1_e2 454 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d8_m1_e1 456 458 448 1 2.000000E+00 +E_m_pz_d8_m1_e2 458 1 452 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d8_m1_e1 457 459 450 1 2.000000E+00 +E_m_mz_d8_m1_e2 459 1 453 1 -1.000000E+00 +* +* DOMAIN 9 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d9_c1_e1 60 464 +Vmeas_mode_decomp_d9_c2_e1 61 468 +Vmeas_mode_decomp_d9_c3_e1 62 472 +Vmeas_mode_decomp_d9_c4_e1 63 476 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d9_c1_m1_e1 464 465 460 1 4.99997010E-01 +E_mode_decomp_d9_c1_m2_e1 465 466 461 1 6.60299603E-01 +E_mode_decomp_d9_c1_m3_e1 466 467 462 1 -2.52110920E-01 +E_mode_decomp_d9_c1_m4_e1 467 1 463 1 5.00566867E-01 +E_mode_decomp_d9_c2_m1_e1 468 469 460 1 5.00000814E-01 +E_mode_decomp_d9_c2_m2_e1 469 470 461 1 2.52638434E-01 +E_mode_decomp_d9_c2_m3_e1 470 471 462 1 6.60216363E-01 +E_mode_decomp_d9_c2_m4_e1 471 1 463 1 -5.00372583E-01 +E_mode_decomp_d9_c3_m1_e1 472 473 460 1 5.00001652E-01 +E_mode_decomp_d9_c3_m2_e1 473 474 461 1 -6.60745021E-01 +E_mode_decomp_d9_c3_m3_e1 474 475 462 1 2.52713880E-01 +E_mode_decomp_d9_c3_m4_e1 475 1 463 1 4.99437438E-01 +E_mode_decomp_d9_c4_m1_e1 476 477 460 1 5.00000524E-01 +E_mode_decomp_d9_c4_m2_e1 477 478 461 1 -2.52179072E-01 +E_mode_decomp_d9_c4_m3_e1 478 479 462 1 -6.60825366E-01 +E_mode_decomp_d9_c4_m4_e1 479 1 463 1 -4.99622234E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d9_c1_m1_e1 1 460 Vmeas_mode_decomp_d9_c1_e1 4.99997010E-01 +F_mode_decomp_d9_c2_m1_e1 1 460 Vmeas_mode_decomp_d9_c2_e1 5.00000814E-01 +F_mode_decomp_d9_c3_m1_e1 1 460 Vmeas_mode_decomp_d9_c3_e1 5.00001652E-01 +F_mode_decomp_d9_c4_m1_e1 1 460 Vmeas_mode_decomp_d9_c4_e1 5.00000524E-01 +F_mode_decomp_d9_c1_m2_e1 1 461 Vmeas_mode_decomp_d9_c1_e1 6.60299603E-01 +F_mode_decomp_d9_c2_m2_e1 1 461 Vmeas_mode_decomp_d9_c2_e1 2.52638434E-01 +F_mode_decomp_d9_c3_m2_e1 1 461 Vmeas_mode_decomp_d9_c3_e1 -6.60745021E-01 +F_mode_decomp_d9_c4_m2_e1 1 461 Vmeas_mode_decomp_d9_c4_e1 -2.52179072E-01 +F_mode_decomp_d9_c1_m3_e1 1 462 Vmeas_mode_decomp_d9_c1_e1 -2.52110920E-01 +F_mode_decomp_d9_c2_m3_e1 1 462 Vmeas_mode_decomp_d9_c2_e1 6.60216363E-01 +F_mode_decomp_d9_c3_m3_e1 1 462 Vmeas_mode_decomp_d9_c3_e1 2.52713880E-01 +F_mode_decomp_d9_c4_m3_e1 1 462 Vmeas_mode_decomp_d9_c4_e1 -6.60825366E-01 +F_mode_decomp_d9_c1_m4_e1 1 463 Vmeas_mode_decomp_d9_c1_e1 5.00566867E-01 +F_mode_decomp_d9_c2_m4_e1 1 463 Vmeas_mode_decomp_d9_c2_e1 -5.00372583E-01 +F_mode_decomp_d9_c3_m4_e1 1 463 Vmeas_mode_decomp_d9_c3_e1 4.99437438E-01 +F_mode_decomp_d9_c4_m4_e1 1 463 Vmeas_mode_decomp_d9_c4_e1 -4.99622234E-01 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d9_c1_e2 216 484 +Vmeas_mode_decomp_d9_c2_e2 217 488 +Vmeas_mode_decomp_d9_c3_e2 218 492 +Vmeas_mode_decomp_d9_c4_e2 219 496 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d9_c1_m1_e2 484 485 480 1 4.99997010E-01 +E_mode_decomp_d9_c1_m2_e2 485 486 481 1 6.60299603E-01 +E_mode_decomp_d9_c1_m3_e2 486 487 482 1 -2.52110920E-01 +E_mode_decomp_d9_c1_m4_e2 487 1 483 1 5.00566867E-01 +E_mode_decomp_d9_c2_m1_e2 488 489 480 1 5.00000814E-01 +E_mode_decomp_d9_c2_m2_e2 489 490 481 1 2.52638434E-01 +E_mode_decomp_d9_c2_m3_e2 490 491 482 1 6.60216363E-01 +E_mode_decomp_d9_c2_m4_e2 491 1 483 1 -5.00372583E-01 +E_mode_decomp_d9_c3_m1_e2 492 493 480 1 5.00001652E-01 +E_mode_decomp_d9_c3_m2_e2 493 494 481 1 -6.60745021E-01 +E_mode_decomp_d9_c3_m3_e2 494 495 482 1 2.52713880E-01 +E_mode_decomp_d9_c3_m4_e2 495 1 483 1 4.99437438E-01 +E_mode_decomp_d9_c4_m1_e2 496 497 480 1 5.00000524E-01 +E_mode_decomp_d9_c4_m2_e2 497 498 481 1 -2.52179072E-01 +E_mode_decomp_d9_c4_m3_e2 498 499 482 1 -6.60825366E-01 +E_mode_decomp_d9_c4_m4_e2 499 1 483 1 -4.99622234E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d9_c1_m1_e2 1 480 Vmeas_mode_decomp_d9_c1_e2 4.99997010E-01 +F_mode_decomp_d9_c2_m1_e2 1 480 Vmeas_mode_decomp_d9_c2_e2 5.00000814E-01 +F_mode_decomp_d9_c3_m1_e2 1 480 Vmeas_mode_decomp_d9_c3_e2 5.00001652E-01 +F_mode_decomp_d9_c4_m1_e2 1 480 Vmeas_mode_decomp_d9_c4_e2 5.00000524E-01 +F_mode_decomp_d9_c1_m2_e2 1 481 Vmeas_mode_decomp_d9_c1_e2 6.60299603E-01 +F_mode_decomp_d9_c2_m2_e2 1 481 Vmeas_mode_decomp_d9_c2_e2 2.52638434E-01 +F_mode_decomp_d9_c3_m2_e2 1 481 Vmeas_mode_decomp_d9_c3_e2 -6.60745021E-01 +F_mode_decomp_d9_c4_m2_e2 1 481 Vmeas_mode_decomp_d9_c4_e2 -2.52179072E-01 +F_mode_decomp_d9_c1_m3_e2 1 482 Vmeas_mode_decomp_d9_c1_e2 -2.52110920E-01 +F_mode_decomp_d9_c2_m3_e2 1 482 Vmeas_mode_decomp_d9_c2_e2 6.60216363E-01 +F_mode_decomp_d9_c3_m3_e2 1 482 Vmeas_mode_decomp_d9_c3_e2 2.52713880E-01 +F_mode_decomp_d9_c4_m3_e2 1 482 Vmeas_mode_decomp_d9_c4_e2 -6.60825366E-01 +F_mode_decomp_d9_c1_m4_e2 1 483 Vmeas_mode_decomp_d9_c1_e2 5.00566867E-01 +F_mode_decomp_d9_c2_m4_e2 1 483 Vmeas_mode_decomp_d9_c2_e2 -5.00372583E-01 +F_mode_decomp_d9_c3_m4_e2 1 483 Vmeas_mode_decomp_d9_c3_e2 4.99437438E-01 +F_mode_decomp_d9_c4_m4_e2 1 483 Vmeas_mode_decomp_d9_c4_e2 -4.99622234E-01 +* +* Modal impedance: end1 +* +RZCm_d9_m1_e1 460 500 9.322448E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m1_e2 480 501 9.322448E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m1_e1 500 1 502 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m1_e2 501 1 503 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m1_e1 503 1 504 1 LTRA_T_pz_d9_m1_e1 +.MODEL LTRA_T_pz_d9_m1_e1 LTRA( R=0.0 L= 3.236033E-07 C= 3.723514E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m1_e2 502 1 505 1 LTRA_T_mz_d9_m1_e2 +.MODEL LTRA_T_mz_d9_m1_e2 LTRA( R=0.0 L= 3.236033E-07 C= 3.723514E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m1_e1 503 1 9.322448E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m1_e2 502 1 9.322448E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m1_e1 504 506 460 1 2.000000E+00 +E_m_pz_d9_m1_e2 506 1 500 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m1_e1 505 507 480 1 2.000000E+00 +E_m_mz_d9_m1_e2 507 1 501 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m2_e1 461 508 4.294265E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m2_e2 481 509 4.294265E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m2_e1 508 1 510 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m2_e2 509 1 511 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m2_e1 511 1 512 1 LTRA_T_pz_d9_m2_e1 +.MODEL LTRA_T_pz_d9_m2_e1 LTRA( R=0.0 L= 1.530171E-07 C= 8.297789E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m2_e2 510 1 513 1 LTRA_T_mz_d9_m2_e2 +.MODEL LTRA_T_mz_d9_m2_e2 LTRA( R=0.0 L= 1.530171E-07 C= 8.297789E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m2_e1 511 1 4.294265E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m2_e2 510 1 4.294265E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m2_e1 512 514 461 1 2.000000E+00 +E_m_pz_d9_m2_e2 514 1 508 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m2_e1 513 515 481 1 2.000000E+00 +E_m_mz_d9_m2_e2 515 1 509 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m3_e1 462 516 4.294177E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m3_e2 482 517 4.294177E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m3_e1 516 1 518 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m3_e2 517 1 519 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m3_e1 519 1 520 1 LTRA_T_pz_d9_m3_e1 +.MODEL LTRA_T_pz_d9_m3_e1 LTRA( R=0.0 L= 1.530143E-07 C= 8.297977E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m3_e2 518 1 521 1 LTRA_T_mz_d9_m3_e2 +.MODEL LTRA_T_mz_d9_m3_e2 LTRA( R=0.0 L= 1.530143E-07 C= 8.297977E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m3_e1 519 1 4.294177E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m3_e2 518 1 4.294177E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m3_e1 520 522 462 1 2.000000E+00 +E_m_pz_d9_m3_e2 522 1 516 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m3_e1 521 523 482 1 2.000000E+00 +E_m_mz_d9_m3_e2 523 1 517 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m4_e1 463 524 2.983334E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m4_e2 483 525 2.983334E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m4_e1 524 1 526 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m4_e2 525 1 527 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m4_e1 527 1 528 1 LTRA_T_pz_d9_m4_e1 +.MODEL LTRA_T_pz_d9_m4_e1 LTRA( R=0.0 L= 1.076602E-07 C= 1.209627E-10 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m4_e2 526 1 529 1 LTRA_T_mz_d9_m4_e2 +.MODEL LTRA_T_mz_d9_m4_e2 LTRA( R=0.0 L= 1.076602E-07 C= 1.209627E-10 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m4_e1 527 1 2.983334E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m4_e2 526 1 2.983334E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m4_e1 528 530 463 1 2.000000E+00 +E_m_pz_d9_m4_e2 530 1 524 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m4_e1 529 531 483 1 2.000000E+00 +E_m_mz_d9_m4_e2 531 1 525 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_Ngspice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_Ngspice.lib new file mode 100644 index 0000000..821d1f0 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_Ngspice.lib @@ -0,0 +1,1568 @@ +* Ngspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 +* node: 3 Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 +* node: 4 Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 +* node: 5 Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 +* node: 6 Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 +* node: 7 Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 +* node: 8 Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 +* node: 9 Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 +* node: 10 Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 +* node: 11 Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 +* node: 12 Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 +* node: 13 Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 +* node: 14 Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield +* +* End 2 nodes: +* +* node: 15 Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 +* node: 16 Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 +* node: 17 Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 +* node: 18 Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 +* node: 19 Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 +* node: 20 Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 +* node: 21 Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 +* node: 22 Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 +* node: 23 Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 +* node: 24 Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 +* node: 25 Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 +* node: 26 Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 +* node: 27 Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield +* +.subckt ZT_FD_Spacewire ++ 2 3 4 5 6 7 8 9 10 11 12 13 14 ++ 15 16 17 18 19 20 21 22 23 24 25 26 27 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 28 5.092958E-02 +Rdc_c2_e1 3 29 5.092958E-02 +Rdc_c3_e1 4 30 5.092958E-02 +Rdc_c4_e1 5 31 5.092958E-02 +Rdc_c5_e1 6 32 5.092958E-02 +Rdc_c6_e1 7 33 5.092958E-02 +Rdc_c7_e1 8 34 5.092958E-02 +Rdc_c8_e1 9 35 5.092958E-02 +Rdc_c9_e1 10 36 1.273240E-02 +Rdc_c10_e1 11 37 1.273240E-02 +Rdc_c11_e1 12 38 1.273240E-02 +Rdc_c12_e1 13 39 1.273240E-02 +Rdc_c13_e1 14 1 3.395291E-03 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 15 40 5.092958E-02 +Rdc_c2_e2 16 41 5.092958E-02 +Rdc_c3_e2 17 42 5.092958E-02 +Rdc_c4_e2 18 43 5.092958E-02 +Rdc_c5_e2 19 44 5.092958E-02 +Rdc_c6_e2 20 45 5.092958E-02 +Rdc_c7_e2 21 46 5.092958E-02 +Rdc_c8_e2 22 47 5.092958E-02 +Rdc_c9_e2 23 48 1.273240E-02 +Rdc_c10_e2 24 49 1.273240E-02 +Rdc_c11_e2 25 50 1.273240E-02 +Rdc_c12_e2 26 51 1.273240E-02 +Rdc_c13_e2 27 1 3.395291E-03 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 28 64 +Vmeas_domain_decomp_c2_e1 29 76 +Vmeas_domain_decomp_c3_e1 30 88 +Vmeas_domain_decomp_c4_e1 31 100 +Vmeas_domain_decomp_c5_e1 32 112 +Vmeas_domain_decomp_c6_e1 33 124 +Vmeas_domain_decomp_c7_e1 34 136 +Vmeas_domain_decomp_c8_e1 35 148 +Vmeas_domain_decomp_c9_e1 36 160 +Vmeas_domain_decomp_c10_e1 37 172 +Vmeas_domain_decomp_c11_e1 38 184 +Vmeas_domain_decomp_c12_e1 39 196 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 64 65 52 1 5.000000E-01 +E_domain_decomp_c1_dc2_e1 65 66 53 1 1.000000E+00 +E_domain_decomp_c1_dc3_e1 66 67 54 1 0.000000E+00 +E_domain_decomp_c1_dc4_e1 67 68 55 1 0.000000E+00 +E_domain_decomp_c1_dc5_e1 68 69 56 1 0.000000E+00 +E_domain_decomp_c1_dc6_e1 69 70 57 1 0.000000E+00 +E_domain_decomp_c1_dc7_e1 70 71 58 1 0.000000E+00 +E_domain_decomp_c1_dc8_e1 71 72 59 1 -0.000000E+00 +E_domain_decomp_c1_dc9_e1 72 73 60 1 1.000000E+00 +E_domain_decomp_c1_dc10_e1 73 74 61 1 0.000000E+00 +E_domain_decomp_c1_dc11_e1 74 75 62 1 0.000000E+00 +E_domain_decomp_c1_dc12_e1 75 1 63 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e1 76 77 52 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e1 77 78 53 1 1.000000E+00 +E_domain_decomp_c2_dc3_e1 78 79 54 1 0.000000E+00 +E_domain_decomp_c2_dc4_e1 79 80 55 1 0.000000E+00 +E_domain_decomp_c2_dc5_e1 80 81 56 1 0.000000E+00 +E_domain_decomp_c2_dc6_e1 81 82 57 1 0.000000E+00 +E_domain_decomp_c2_dc7_e1 82 83 58 1 0.000000E+00 +E_domain_decomp_c2_dc8_e1 83 84 59 1 -0.000000E+00 +E_domain_decomp_c2_dc9_e1 84 85 60 1 1.000000E+00 +E_domain_decomp_c2_dc10_e1 85 86 61 1 0.000000E+00 +E_domain_decomp_c2_dc11_e1 86 87 62 1 0.000000E+00 +E_domain_decomp_c2_dc12_e1 87 1 63 1 -0.000000E+00 +E_domain_decomp_c3_dc1_e1 88 89 52 1 0.000000E+00 +E_domain_decomp_c3_dc2_e1 89 90 53 1 0.000000E+00 +E_domain_decomp_c3_dc3_e1 90 91 54 1 5.000000E-01 +E_domain_decomp_c3_dc4_e1 91 92 55 1 1.000000E+00 +E_domain_decomp_c3_dc5_e1 92 93 56 1 0.000000E+00 +E_domain_decomp_c3_dc6_e1 93 94 57 1 0.000000E+00 +E_domain_decomp_c3_dc7_e1 94 95 58 1 0.000000E+00 +E_domain_decomp_c3_dc8_e1 95 96 59 1 0.000000E+00 +E_domain_decomp_c3_dc9_e1 96 97 60 1 -0.000000E+00 +E_domain_decomp_c3_dc10_e1 97 98 61 1 1.000000E+00 +E_domain_decomp_c3_dc11_e1 98 99 62 1 0.000000E+00 +E_domain_decomp_c3_dc12_e1 99 1 63 1 -0.000000E+00 +E_domain_decomp_c4_dc1_e1 100 101 52 1 0.000000E+00 +E_domain_decomp_c4_dc2_e1 101 102 53 1 0.000000E+00 +E_domain_decomp_c4_dc3_e1 102 103 54 1 -5.000000E-01 +E_domain_decomp_c4_dc4_e1 103 104 55 1 1.000000E+00 +E_domain_decomp_c4_dc5_e1 104 105 56 1 0.000000E+00 +E_domain_decomp_c4_dc6_e1 105 106 57 1 0.000000E+00 +E_domain_decomp_c4_dc7_e1 106 107 58 1 0.000000E+00 +E_domain_decomp_c4_dc8_e1 107 108 59 1 0.000000E+00 +E_domain_decomp_c4_dc9_e1 108 109 60 1 -0.000000E+00 +E_domain_decomp_c4_dc10_e1 109 110 61 1 1.000000E+00 +E_domain_decomp_c4_dc11_e1 110 111 62 1 0.000000E+00 +E_domain_decomp_c4_dc12_e1 111 1 63 1 -0.000000E+00 +E_domain_decomp_c5_dc1_e1 112 113 52 1 0.000000E+00 +E_domain_decomp_c5_dc2_e1 113 114 53 1 0.000000E+00 +E_domain_decomp_c5_dc3_e1 114 115 54 1 0.000000E+00 +E_domain_decomp_c5_dc4_e1 115 116 55 1 0.000000E+00 +E_domain_decomp_c5_dc5_e1 116 117 56 1 5.000000E-01 +E_domain_decomp_c5_dc6_e1 117 118 57 1 1.000000E+00 +E_domain_decomp_c5_dc7_e1 118 119 58 1 0.000000E+00 +E_domain_decomp_c5_dc8_e1 119 120 59 1 0.000000E+00 +E_domain_decomp_c5_dc9_e1 120 121 60 1 0.000000E+00 +E_domain_decomp_c5_dc10_e1 121 122 61 1 -0.000000E+00 +E_domain_decomp_c5_dc11_e1 122 123 62 1 1.000000E+00 +E_domain_decomp_c5_dc12_e1 123 1 63 1 -0.000000E+00 +E_domain_decomp_c6_dc1_e1 124 125 52 1 0.000000E+00 +E_domain_decomp_c6_dc2_e1 125 126 53 1 0.000000E+00 +E_domain_decomp_c6_dc3_e1 126 127 54 1 0.000000E+00 +E_domain_decomp_c6_dc4_e1 127 128 55 1 0.000000E+00 +E_domain_decomp_c6_dc5_e1 128 129 56 1 -5.000000E-01 +E_domain_decomp_c6_dc6_e1 129 130 57 1 1.000000E+00 +E_domain_decomp_c6_dc7_e1 130 131 58 1 0.000000E+00 +E_domain_decomp_c6_dc8_e1 131 132 59 1 0.000000E+00 +E_domain_decomp_c6_dc9_e1 132 133 60 1 0.000000E+00 +E_domain_decomp_c6_dc10_e1 133 134 61 1 -0.000000E+00 +E_domain_decomp_c6_dc11_e1 134 135 62 1 1.000000E+00 +E_domain_decomp_c6_dc12_e1 135 1 63 1 -0.000000E+00 +E_domain_decomp_c7_dc1_e1 136 137 52 1 0.000000E+00 +E_domain_decomp_c7_dc2_e1 137 138 53 1 0.000000E+00 +E_domain_decomp_c7_dc3_e1 138 139 54 1 0.000000E+00 +E_domain_decomp_c7_dc4_e1 139 140 55 1 0.000000E+00 +E_domain_decomp_c7_dc5_e1 140 141 56 1 0.000000E+00 +E_domain_decomp_c7_dc6_e1 141 142 57 1 0.000000E+00 +E_domain_decomp_c7_dc7_e1 142 143 58 1 5.000000E-01 +E_domain_decomp_c7_dc8_e1 143 144 59 1 1.000000E+00 +E_domain_decomp_c7_dc9_e1 144 145 60 1 0.000000E+00 +E_domain_decomp_c7_dc10_e1 145 146 61 1 0.000000E+00 +E_domain_decomp_c7_dc11_e1 146 147 62 1 -0.000000E+00 +E_domain_decomp_c7_dc12_e1 147 1 63 1 1.000000E+00 +E_domain_decomp_c8_dc1_e1 148 149 52 1 0.000000E+00 +E_domain_decomp_c8_dc2_e1 149 150 53 1 0.000000E+00 +E_domain_decomp_c8_dc3_e1 150 151 54 1 0.000000E+00 +E_domain_decomp_c8_dc4_e1 151 152 55 1 0.000000E+00 +E_domain_decomp_c8_dc5_e1 152 153 56 1 0.000000E+00 +E_domain_decomp_c8_dc6_e1 153 154 57 1 0.000000E+00 +E_domain_decomp_c8_dc7_e1 154 155 58 1 -5.000000E-01 +E_domain_decomp_c8_dc8_e1 155 156 59 1 1.000000E+00 +E_domain_decomp_c8_dc9_e1 156 157 60 1 0.000000E+00 +E_domain_decomp_c8_dc10_e1 157 158 61 1 0.000000E+00 +E_domain_decomp_c8_dc11_e1 158 159 62 1 -0.000000E+00 +E_domain_decomp_c8_dc12_e1 159 1 63 1 1.000000E+00 +E_domain_decomp_c9_dc1_e1 160 161 52 1 0.000000E+00 +E_domain_decomp_c9_dc2_e1 161 162 53 1 0.000000E+00 +E_domain_decomp_c9_dc3_e1 162 163 54 1 0.000000E+00 +E_domain_decomp_c9_dc4_e1 163 164 55 1 0.000000E+00 +E_domain_decomp_c9_dc5_e1 164 165 56 1 0.000000E+00 +E_domain_decomp_c9_dc6_e1 165 166 57 1 0.000000E+00 +E_domain_decomp_c9_dc7_e1 166 167 58 1 0.000000E+00 +E_domain_decomp_c9_dc8_e1 167 168 59 1 -0.000000E+00 +E_domain_decomp_c9_dc9_e1 168 169 60 1 1.000000E+00 +E_domain_decomp_c9_dc10_e1 169 170 61 1 0.000000E+00 +E_domain_decomp_c9_dc11_e1 170 171 62 1 0.000000E+00 +E_domain_decomp_c9_dc12_e1 171 1 63 1 -0.000000E+00 +E_domain_decomp_c10_dc1_e1 172 173 52 1 0.000000E+00 +E_domain_decomp_c10_dc2_e1 173 174 53 1 0.000000E+00 +E_domain_decomp_c10_dc3_e1 174 175 54 1 0.000000E+00 +E_domain_decomp_c10_dc4_e1 175 176 55 1 0.000000E+00 +E_domain_decomp_c10_dc5_e1 176 177 56 1 0.000000E+00 +E_domain_decomp_c10_dc6_e1 177 178 57 1 0.000000E+00 +E_domain_decomp_c10_dc7_e1 178 179 58 1 0.000000E+00 +E_domain_decomp_c10_dc8_e1 179 180 59 1 0.000000E+00 +E_domain_decomp_c10_dc9_e1 180 181 60 1 -0.000000E+00 +E_domain_decomp_c10_dc10_e1 181 182 61 1 1.000000E+00 +E_domain_decomp_c10_dc11_e1 182 183 62 1 0.000000E+00 +E_domain_decomp_c10_dc12_e1 183 1 63 1 -0.000000E+00 +E_domain_decomp_c11_dc1_e1 184 185 52 1 0.000000E+00 +E_domain_decomp_c11_dc2_e1 185 186 53 1 0.000000E+00 +E_domain_decomp_c11_dc3_e1 186 187 54 1 0.000000E+00 +E_domain_decomp_c11_dc4_e1 187 188 55 1 0.000000E+00 +E_domain_decomp_c11_dc5_e1 188 189 56 1 0.000000E+00 +E_domain_decomp_c11_dc6_e1 189 190 57 1 0.000000E+00 +E_domain_decomp_c11_dc7_e1 190 191 58 1 0.000000E+00 +E_domain_decomp_c11_dc8_e1 191 192 59 1 0.000000E+00 +E_domain_decomp_c11_dc9_e1 192 193 60 1 0.000000E+00 +E_domain_decomp_c11_dc10_e1 193 194 61 1 -0.000000E+00 +E_domain_decomp_c11_dc11_e1 194 195 62 1 1.000000E+00 +E_domain_decomp_c11_dc12_e1 195 1 63 1 -0.000000E+00 +E_domain_decomp_c12_dc1_e1 196 197 52 1 0.000000E+00 +E_domain_decomp_c12_dc2_e1 197 198 53 1 0.000000E+00 +E_domain_decomp_c12_dc3_e1 198 199 54 1 0.000000E+00 +E_domain_decomp_c12_dc4_e1 199 200 55 1 0.000000E+00 +E_domain_decomp_c12_dc5_e1 200 201 56 1 0.000000E+00 +E_domain_decomp_c12_dc6_e1 201 202 57 1 0.000000E+00 +E_domain_decomp_c12_dc7_e1 202 203 58 1 0.000000E+00 +E_domain_decomp_c12_dc8_e1 203 204 59 1 0.000000E+00 +E_domain_decomp_c12_dc9_e1 204 205 60 1 0.000000E+00 +E_domain_decomp_c12_dc10_e1 205 206 61 1 0.000000E+00 +E_domain_decomp_c12_dc11_e1 206 207 62 1 -0.000000E+00 +E_domain_decomp_c12_dc12_e1 207 1 63 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 52 Vmeas_domain_decomp_c1_e1 5.000000E-01 +F_domain_decomp_c2_dc1_e1 1 52 Vmeas_domain_decomp_c2_e1 -5.000000E-01 +F_domain_decomp_c3_dc1_e1 1 52 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc1_e1 1 52 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc1_e1 1 52 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc1_e1 1 52 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc1_e1 1 52 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc1_e1 1 52 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc1_e1 1 52 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc1_e1 1 52 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc1_e1 1 52 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc1_e1 1 52 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 53 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 53 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c3_dc2_e1 1 53 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc2_e1 1 53 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc2_e1 1 53 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc2_e1 1 53 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc2_e1 1 53 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc2_e1 1 53 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc2_e1 1 53 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc2_e1 1 53 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc2_e1 1 53 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc2_e1 1 53 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc3_e1 1 54 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc3_e1 1 54 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc3_e1 1 54 Vmeas_domain_decomp_c3_e1 5.000000E-01 +F_domain_decomp_c4_dc3_e1 1 54 Vmeas_domain_decomp_c4_e1 -5.000000E-01 +F_domain_decomp_c5_dc3_e1 1 54 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc3_e1 1 54 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc3_e1 1 54 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc3_e1 1 54 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc3_e1 1 54 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc3_e1 1 54 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc3_e1 1 54 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc3_e1 1 54 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc4_e1 1 55 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc4_e1 1 55 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc4_e1 1 55 Vmeas_domain_decomp_c3_e1 1.000000E+00 +F_domain_decomp_c4_dc4_e1 1 55 Vmeas_domain_decomp_c4_e1 1.000000E+00 +F_domain_decomp_c5_dc4_e1 1 55 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc4_e1 1 55 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc4_e1 1 55 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc4_e1 1 55 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc4_e1 1 55 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc4_e1 1 55 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc4_e1 1 55 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc4_e1 1 55 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc5_e1 1 56 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc5_e1 1 56 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc5_e1 1 56 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc5_e1 1 56 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc5_e1 1 56 Vmeas_domain_decomp_c5_e1 5.000000E-01 +F_domain_decomp_c6_dc5_e1 1 56 Vmeas_domain_decomp_c6_e1 -5.000000E-01 +F_domain_decomp_c7_dc5_e1 1 56 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc5_e1 1 56 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc5_e1 1 56 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc5_e1 1 56 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc5_e1 1 56 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc5_e1 1 56 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc6_e1 1 57 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc6_e1 1 57 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc6_e1 1 57 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc6_e1 1 57 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc6_e1 1 57 Vmeas_domain_decomp_c5_e1 1.000000E+00 +F_domain_decomp_c6_dc6_e1 1 57 Vmeas_domain_decomp_c6_e1 1.000000E+00 +F_domain_decomp_c7_dc6_e1 1 57 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc6_e1 1 57 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc6_e1 1 57 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc6_e1 1 57 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc6_e1 1 57 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc6_e1 1 57 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc7_e1 1 58 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc7_e1 1 58 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc7_e1 1 58 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc7_e1 1 58 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc7_e1 1 58 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc7_e1 1 58 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc7_e1 1 58 Vmeas_domain_decomp_c7_e1 5.000000E-01 +F_domain_decomp_c8_dc7_e1 1 58 Vmeas_domain_decomp_c8_e1 -5.000000E-01 +F_domain_decomp_c9_dc7_e1 1 58 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc7_e1 1 58 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc7_e1 1 58 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc7_e1 1 58 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc8_e1 1 59 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc8_e1 1 59 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc8_e1 1 59 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc8_e1 1 59 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc8_e1 1 59 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc8_e1 1 59 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc8_e1 1 59 Vmeas_domain_decomp_c7_e1 1.000000E+00 +F_domain_decomp_c8_dc8_e1 1 59 Vmeas_domain_decomp_c8_e1 1.000000E+00 +F_domain_decomp_c9_dc8_e1 1 59 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc8_e1 1 59 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc8_e1 1 59 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc8_e1 1 59 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc9_e1 1 60 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc9_e1 1 60 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c3_dc9_e1 1 60 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc9_e1 1 60 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc9_e1 1 60 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc9_e1 1 60 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc9_e1 1 60 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc9_e1 1 60 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc9_e1 1 60 Vmeas_domain_decomp_c9_e1 1.000000E+00 +F_domain_decomp_c10_dc9_e1 1 60 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc9_e1 1 60 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc9_e1 1 60 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc10_e1 1 61 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc10_e1 1 61 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc10_e1 1 61 Vmeas_domain_decomp_c3_e1 1.000000E+00 +F_domain_decomp_c4_dc10_e1 1 61 Vmeas_domain_decomp_c4_e1 1.000000E+00 +F_domain_decomp_c5_dc10_e1 1 61 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc10_e1 1 61 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc10_e1 1 61 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc10_e1 1 61 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc10_e1 1 61 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc10_e1 1 61 Vmeas_domain_decomp_c10_e1 1.000000E+00 +F_domain_decomp_c11_dc10_e1 1 61 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc10_e1 1 61 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc11_e1 1 62 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc11_e1 1 62 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc11_e1 1 62 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc11_e1 1 62 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc11_e1 1 62 Vmeas_domain_decomp_c5_e1 1.000000E+00 +F_domain_decomp_c6_dc11_e1 1 62 Vmeas_domain_decomp_c6_e1 1.000000E+00 +F_domain_decomp_c7_dc11_e1 1 62 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc11_e1 1 62 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc11_e1 1 62 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc11_e1 1 62 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc11_e1 1 62 Vmeas_domain_decomp_c11_e1 1.000000E+00 +F_domain_decomp_c12_dc11_e1 1 62 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc12_e1 1 63 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc12_e1 1 63 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc12_e1 1 63 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc12_e1 1 63 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc12_e1 1 63 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc12_e1 1 63 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc12_e1 1 63 Vmeas_domain_decomp_c7_e1 1.000000E+00 +F_domain_decomp_c8_dc12_e1 1 63 Vmeas_domain_decomp_c8_e1 1.000000E+00 +F_domain_decomp_c9_dc12_e1 1 63 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc12_e1 1 63 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc12_e1 1 63 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc12_e1 1 63 Vmeas_domain_decomp_c12_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 40 220 +Vmeas_domain_decomp_c2_e2 41 232 +Vmeas_domain_decomp_c3_e2 42 244 +Vmeas_domain_decomp_c4_e2 43 256 +Vmeas_domain_decomp_c5_e2 44 268 +Vmeas_domain_decomp_c6_e2 45 280 +Vmeas_domain_decomp_c7_e2 46 292 +Vmeas_domain_decomp_c8_e2 47 304 +Vmeas_domain_decomp_c9_e2 48 316 +Vmeas_domain_decomp_c10_e2 49 328 +Vmeas_domain_decomp_c11_e2 50 340 +Vmeas_domain_decomp_c12_e2 51 352 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 220 221 208 1 5.000000E-01 +E_domain_decomp_c1_dc2_e2 221 222 209 1 1.000000E+00 +E_domain_decomp_c1_dc3_e2 222 223 210 1 0.000000E+00 +E_domain_decomp_c1_dc4_e2 223 224 211 1 0.000000E+00 +E_domain_decomp_c1_dc5_e2 224 225 212 1 0.000000E+00 +E_domain_decomp_c1_dc6_e2 225 226 213 1 0.000000E+00 +E_domain_decomp_c1_dc7_e2 226 227 214 1 0.000000E+00 +E_domain_decomp_c1_dc8_e2 227 228 215 1 -0.000000E+00 +E_domain_decomp_c1_dc9_e2 228 229 216 1 1.000000E+00 +E_domain_decomp_c1_dc10_e2 229 230 217 1 0.000000E+00 +E_domain_decomp_c1_dc11_e2 230 231 218 1 0.000000E+00 +E_domain_decomp_c1_dc12_e2 231 1 219 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e2 232 233 208 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e2 233 234 209 1 1.000000E+00 +E_domain_decomp_c2_dc3_e2 234 235 210 1 0.000000E+00 +E_domain_decomp_c2_dc4_e2 235 236 211 1 0.000000E+00 +E_domain_decomp_c2_dc5_e2 236 237 212 1 0.000000E+00 +E_domain_decomp_c2_dc6_e2 237 238 213 1 0.000000E+00 +E_domain_decomp_c2_dc7_e2 238 239 214 1 0.000000E+00 +E_domain_decomp_c2_dc8_e2 239 240 215 1 -0.000000E+00 +E_domain_decomp_c2_dc9_e2 240 241 216 1 1.000000E+00 +E_domain_decomp_c2_dc10_e2 241 242 217 1 0.000000E+00 +E_domain_decomp_c2_dc11_e2 242 243 218 1 0.000000E+00 +E_domain_decomp_c2_dc12_e2 243 1 219 1 -0.000000E+00 +E_domain_decomp_c3_dc1_e2 244 245 208 1 0.000000E+00 +E_domain_decomp_c3_dc2_e2 245 246 209 1 0.000000E+00 +E_domain_decomp_c3_dc3_e2 246 247 210 1 5.000000E-01 +E_domain_decomp_c3_dc4_e2 247 248 211 1 1.000000E+00 +E_domain_decomp_c3_dc5_e2 248 249 212 1 0.000000E+00 +E_domain_decomp_c3_dc6_e2 249 250 213 1 0.000000E+00 +E_domain_decomp_c3_dc7_e2 250 251 214 1 0.000000E+00 +E_domain_decomp_c3_dc8_e2 251 252 215 1 0.000000E+00 +E_domain_decomp_c3_dc9_e2 252 253 216 1 -0.000000E+00 +E_domain_decomp_c3_dc10_e2 253 254 217 1 1.000000E+00 +E_domain_decomp_c3_dc11_e2 254 255 218 1 0.000000E+00 +E_domain_decomp_c3_dc12_e2 255 1 219 1 -0.000000E+00 +E_domain_decomp_c4_dc1_e2 256 257 208 1 0.000000E+00 +E_domain_decomp_c4_dc2_e2 257 258 209 1 0.000000E+00 +E_domain_decomp_c4_dc3_e2 258 259 210 1 -5.000000E-01 +E_domain_decomp_c4_dc4_e2 259 260 211 1 1.000000E+00 +E_domain_decomp_c4_dc5_e2 260 261 212 1 0.000000E+00 +E_domain_decomp_c4_dc6_e2 261 262 213 1 0.000000E+00 +E_domain_decomp_c4_dc7_e2 262 263 214 1 0.000000E+00 +E_domain_decomp_c4_dc8_e2 263 264 215 1 0.000000E+00 +E_domain_decomp_c4_dc9_e2 264 265 216 1 -0.000000E+00 +E_domain_decomp_c4_dc10_e2 265 266 217 1 1.000000E+00 +E_domain_decomp_c4_dc11_e2 266 267 218 1 0.000000E+00 +E_domain_decomp_c4_dc12_e2 267 1 219 1 -0.000000E+00 +E_domain_decomp_c5_dc1_e2 268 269 208 1 0.000000E+00 +E_domain_decomp_c5_dc2_e2 269 270 209 1 0.000000E+00 +E_domain_decomp_c5_dc3_e2 270 271 210 1 0.000000E+00 +E_domain_decomp_c5_dc4_e2 271 272 211 1 0.000000E+00 +E_domain_decomp_c5_dc5_e2 272 273 212 1 5.000000E-01 +E_domain_decomp_c5_dc6_e2 273 274 213 1 1.000000E+00 +E_domain_decomp_c5_dc7_e2 274 275 214 1 0.000000E+00 +E_domain_decomp_c5_dc8_e2 275 276 215 1 0.000000E+00 +E_domain_decomp_c5_dc9_e2 276 277 216 1 0.000000E+00 +E_domain_decomp_c5_dc10_e2 277 278 217 1 -0.000000E+00 +E_domain_decomp_c5_dc11_e2 278 279 218 1 1.000000E+00 +E_domain_decomp_c5_dc12_e2 279 1 219 1 -0.000000E+00 +E_domain_decomp_c6_dc1_e2 280 281 208 1 0.000000E+00 +E_domain_decomp_c6_dc2_e2 281 282 209 1 0.000000E+00 +E_domain_decomp_c6_dc3_e2 282 283 210 1 0.000000E+00 +E_domain_decomp_c6_dc4_e2 283 284 211 1 0.000000E+00 +E_domain_decomp_c6_dc5_e2 284 285 212 1 -5.000000E-01 +E_domain_decomp_c6_dc6_e2 285 286 213 1 1.000000E+00 +E_domain_decomp_c6_dc7_e2 286 287 214 1 0.000000E+00 +E_domain_decomp_c6_dc8_e2 287 288 215 1 0.000000E+00 +E_domain_decomp_c6_dc9_e2 288 289 216 1 0.000000E+00 +E_domain_decomp_c6_dc10_e2 289 290 217 1 -0.000000E+00 +E_domain_decomp_c6_dc11_e2 290 291 218 1 1.000000E+00 +E_domain_decomp_c6_dc12_e2 291 1 219 1 -0.000000E+00 +E_domain_decomp_c7_dc1_e2 292 293 208 1 0.000000E+00 +E_domain_decomp_c7_dc2_e2 293 294 209 1 0.000000E+00 +E_domain_decomp_c7_dc3_e2 294 295 210 1 0.000000E+00 +E_domain_decomp_c7_dc4_e2 295 296 211 1 0.000000E+00 +E_domain_decomp_c7_dc5_e2 296 297 212 1 0.000000E+00 +E_domain_decomp_c7_dc6_e2 297 298 213 1 0.000000E+00 +E_domain_decomp_c7_dc7_e2 298 299 214 1 5.000000E-01 +E_domain_decomp_c7_dc8_e2 299 300 215 1 1.000000E+00 +E_domain_decomp_c7_dc9_e2 300 301 216 1 0.000000E+00 +E_domain_decomp_c7_dc10_e2 301 302 217 1 0.000000E+00 +E_domain_decomp_c7_dc11_e2 302 303 218 1 -0.000000E+00 +E_domain_decomp_c7_dc12_e2 303 1 219 1 1.000000E+00 +E_domain_decomp_c8_dc1_e2 304 305 208 1 0.000000E+00 +E_domain_decomp_c8_dc2_e2 305 306 209 1 0.000000E+00 +E_domain_decomp_c8_dc3_e2 306 307 210 1 0.000000E+00 +E_domain_decomp_c8_dc4_e2 307 308 211 1 0.000000E+00 +E_domain_decomp_c8_dc5_e2 308 309 212 1 0.000000E+00 +E_domain_decomp_c8_dc6_e2 309 310 213 1 0.000000E+00 +E_domain_decomp_c8_dc7_e2 310 311 214 1 -5.000000E-01 +E_domain_decomp_c8_dc8_e2 311 312 215 1 1.000000E+00 +E_domain_decomp_c8_dc9_e2 312 313 216 1 0.000000E+00 +E_domain_decomp_c8_dc10_e2 313 314 217 1 0.000000E+00 +E_domain_decomp_c8_dc11_e2 314 315 218 1 -0.000000E+00 +E_domain_decomp_c8_dc12_e2 315 1 219 1 1.000000E+00 +E_domain_decomp_c9_dc1_e2 316 317 208 1 0.000000E+00 +E_domain_decomp_c9_dc2_e2 317 318 209 1 0.000000E+00 +E_domain_decomp_c9_dc3_e2 318 319 210 1 0.000000E+00 +E_domain_decomp_c9_dc4_e2 319 320 211 1 0.000000E+00 +E_domain_decomp_c9_dc5_e2 320 321 212 1 0.000000E+00 +E_domain_decomp_c9_dc6_e2 321 322 213 1 0.000000E+00 +E_domain_decomp_c9_dc7_e2 322 323 214 1 0.000000E+00 +E_domain_decomp_c9_dc8_e2 323 324 215 1 -0.000000E+00 +E_domain_decomp_c9_dc9_e2 324 325 216 1 1.000000E+00 +E_domain_decomp_c9_dc10_e2 325 326 217 1 0.000000E+00 +E_domain_decomp_c9_dc11_e2 326 327 218 1 0.000000E+00 +E_domain_decomp_c9_dc12_e2 327 1 219 1 -0.000000E+00 +E_domain_decomp_c10_dc1_e2 328 329 208 1 0.000000E+00 +E_domain_decomp_c10_dc2_e2 329 330 209 1 0.000000E+00 +E_domain_decomp_c10_dc3_e2 330 331 210 1 0.000000E+00 +E_domain_decomp_c10_dc4_e2 331 332 211 1 0.000000E+00 +E_domain_decomp_c10_dc5_e2 332 333 212 1 0.000000E+00 +E_domain_decomp_c10_dc6_e2 333 334 213 1 0.000000E+00 +E_domain_decomp_c10_dc7_e2 334 335 214 1 0.000000E+00 +E_domain_decomp_c10_dc8_e2 335 336 215 1 0.000000E+00 +E_domain_decomp_c10_dc9_e2 336 337 216 1 -0.000000E+00 +E_domain_decomp_c10_dc10_e2 337 338 217 1 1.000000E+00 +E_domain_decomp_c10_dc11_e2 338 339 218 1 0.000000E+00 +E_domain_decomp_c10_dc12_e2 339 1 219 1 -0.000000E+00 +E_domain_decomp_c11_dc1_e2 340 341 208 1 0.000000E+00 +E_domain_decomp_c11_dc2_e2 341 342 209 1 0.000000E+00 +E_domain_decomp_c11_dc3_e2 342 343 210 1 0.000000E+00 +E_domain_decomp_c11_dc4_e2 343 344 211 1 0.000000E+00 +E_domain_decomp_c11_dc5_e2 344 345 212 1 0.000000E+00 +E_domain_decomp_c11_dc6_e2 345 346 213 1 0.000000E+00 +E_domain_decomp_c11_dc7_e2 346 347 214 1 0.000000E+00 +E_domain_decomp_c11_dc8_e2 347 348 215 1 0.000000E+00 +E_domain_decomp_c11_dc9_e2 348 349 216 1 0.000000E+00 +E_domain_decomp_c11_dc10_e2 349 350 217 1 -0.000000E+00 +E_domain_decomp_c11_dc11_e2 350 351 218 1 1.000000E+00 +E_domain_decomp_c11_dc12_e2 351 1 219 1 -0.000000E+00 +E_domain_decomp_c12_dc1_e2 352 353 208 1 0.000000E+00 +E_domain_decomp_c12_dc2_e2 353 354 209 1 0.000000E+00 +E_domain_decomp_c12_dc3_e2 354 355 210 1 0.000000E+00 +E_domain_decomp_c12_dc4_e2 355 356 211 1 0.000000E+00 +E_domain_decomp_c12_dc5_e2 356 357 212 1 0.000000E+00 +E_domain_decomp_c12_dc6_e2 357 358 213 1 0.000000E+00 +E_domain_decomp_c12_dc7_e2 358 359 214 1 0.000000E+00 +E_domain_decomp_c12_dc8_e2 359 360 215 1 0.000000E+00 +E_domain_decomp_c12_dc9_e2 360 361 216 1 0.000000E+00 +E_domain_decomp_c12_dc10_e2 361 362 217 1 0.000000E+00 +E_domain_decomp_c12_dc11_e2 362 363 218 1 -0.000000E+00 +E_domain_decomp_c12_dc12_e2 363 1 219 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 208 Vmeas_domain_decomp_c1_e2 5.000000E-01 +F_domain_decomp_c2_dc1_e2 1 208 Vmeas_domain_decomp_c2_e2 -5.000000E-01 +F_domain_decomp_c3_dc1_e2 1 208 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc1_e2 1 208 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc1_e2 1 208 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc1_e2 1 208 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc1_e2 1 208 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc1_e2 1 208 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc1_e2 1 208 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc1_e2 1 208 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc1_e2 1 208 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc1_e2 1 208 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 209 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 209 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c3_dc2_e2 1 209 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc2_e2 1 209 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc2_e2 1 209 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc2_e2 1 209 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc2_e2 1 209 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc2_e2 1 209 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc2_e2 1 209 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc2_e2 1 209 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc2_e2 1 209 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc2_e2 1 209 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc3_e2 1 210 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc3_e2 1 210 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc3_e2 1 210 Vmeas_domain_decomp_c3_e2 5.000000E-01 +F_domain_decomp_c4_dc3_e2 1 210 Vmeas_domain_decomp_c4_e2 -5.000000E-01 +F_domain_decomp_c5_dc3_e2 1 210 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc3_e2 1 210 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc3_e2 1 210 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc3_e2 1 210 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc3_e2 1 210 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc3_e2 1 210 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc3_e2 1 210 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc3_e2 1 210 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc4_e2 1 211 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc4_e2 1 211 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc4_e2 1 211 Vmeas_domain_decomp_c3_e2 1.000000E+00 +F_domain_decomp_c4_dc4_e2 1 211 Vmeas_domain_decomp_c4_e2 1.000000E+00 +F_domain_decomp_c5_dc4_e2 1 211 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc4_e2 1 211 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc4_e2 1 211 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc4_e2 1 211 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc4_e2 1 211 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc4_e2 1 211 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc4_e2 1 211 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc4_e2 1 211 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc5_e2 1 212 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc5_e2 1 212 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc5_e2 1 212 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc5_e2 1 212 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc5_e2 1 212 Vmeas_domain_decomp_c5_e2 5.000000E-01 +F_domain_decomp_c6_dc5_e2 1 212 Vmeas_domain_decomp_c6_e2 -5.000000E-01 +F_domain_decomp_c7_dc5_e2 1 212 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc5_e2 1 212 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc5_e2 1 212 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc5_e2 1 212 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc5_e2 1 212 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc5_e2 1 212 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc6_e2 1 213 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc6_e2 1 213 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc6_e2 1 213 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc6_e2 1 213 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc6_e2 1 213 Vmeas_domain_decomp_c5_e2 1.000000E+00 +F_domain_decomp_c6_dc6_e2 1 213 Vmeas_domain_decomp_c6_e2 1.000000E+00 +F_domain_decomp_c7_dc6_e2 1 213 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc6_e2 1 213 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc6_e2 1 213 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc6_e2 1 213 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc6_e2 1 213 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc6_e2 1 213 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc7_e2 1 214 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc7_e2 1 214 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc7_e2 1 214 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc7_e2 1 214 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc7_e2 1 214 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc7_e2 1 214 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc7_e2 1 214 Vmeas_domain_decomp_c7_e2 5.000000E-01 +F_domain_decomp_c8_dc7_e2 1 214 Vmeas_domain_decomp_c8_e2 -5.000000E-01 +F_domain_decomp_c9_dc7_e2 1 214 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc7_e2 1 214 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc7_e2 1 214 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc7_e2 1 214 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc8_e2 1 215 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc8_e2 1 215 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc8_e2 1 215 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc8_e2 1 215 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc8_e2 1 215 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc8_e2 1 215 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc8_e2 1 215 Vmeas_domain_decomp_c7_e2 1.000000E+00 +F_domain_decomp_c8_dc8_e2 1 215 Vmeas_domain_decomp_c8_e2 1.000000E+00 +F_domain_decomp_c9_dc8_e2 1 215 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc8_e2 1 215 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc8_e2 1 215 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc8_e2 1 215 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc9_e2 1 216 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc9_e2 1 216 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c3_dc9_e2 1 216 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc9_e2 1 216 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc9_e2 1 216 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc9_e2 1 216 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc9_e2 1 216 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc9_e2 1 216 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc9_e2 1 216 Vmeas_domain_decomp_c9_e2 1.000000E+00 +F_domain_decomp_c10_dc9_e2 1 216 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc9_e2 1 216 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc9_e2 1 216 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc10_e2 1 217 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc10_e2 1 217 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc10_e2 1 217 Vmeas_domain_decomp_c3_e2 1.000000E+00 +F_domain_decomp_c4_dc10_e2 1 217 Vmeas_domain_decomp_c4_e2 1.000000E+00 +F_domain_decomp_c5_dc10_e2 1 217 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc10_e2 1 217 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc10_e2 1 217 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc10_e2 1 217 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc10_e2 1 217 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc10_e2 1 217 Vmeas_domain_decomp_c10_e2 1.000000E+00 +F_domain_decomp_c11_dc10_e2 1 217 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc10_e2 1 217 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc11_e2 1 218 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc11_e2 1 218 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc11_e2 1 218 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc11_e2 1 218 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc11_e2 1 218 Vmeas_domain_decomp_c5_e2 1.000000E+00 +F_domain_decomp_c6_dc11_e2 1 218 Vmeas_domain_decomp_c6_e2 1.000000E+00 +F_domain_decomp_c7_dc11_e2 1 218 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc11_e2 1 218 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc11_e2 1 218 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc11_e2 1 218 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc11_e2 1 218 Vmeas_domain_decomp_c11_e2 1.000000E+00 +F_domain_decomp_c12_dc11_e2 1 218 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc12_e2 1 219 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc12_e2 1 219 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc12_e2 1 219 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc12_e2 1 219 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc12_e2 1 219 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc12_e2 1 219 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc12_e2 1 219 Vmeas_domain_decomp_c7_e2 1.000000E+00 +F_domain_decomp_c8_dc12_e2 1 219 Vmeas_domain_decomp_c8_e2 1.000000E+00 +F_domain_decomp_c9_dc12_e2 1 219 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc12_e2 1 219 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc12_e2 1 219 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc12_e2 1 219 Vmeas_domain_decomp_c12_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 52 365 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 365 1 364 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 364 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 208 367 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 367 1 366 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 366 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 364 368 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 366 369 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 368 1 370 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 369 1 371 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 371 1 372 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 370 1 373 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 371 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 370 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 372 374 364 1 2.000000E+00 +E_m_pz_d1_m1_e2 374 1 368 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 373 375 366 1 2.000000E+00 +E_m_mz_d1_m1_e2 375 1 369 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 53 377 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 377 1 376 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 376 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 209 379 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 379 1 378 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 378 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 376 380 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 378 381 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 380 1 382 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 381 1 383 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d2_m1_e1 383 1 384 1 LTRA_T_pz_d2_m1_e1 +.MODEL LTRA_T_pz_d2_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d2_m1_e2 382 1 385 1 LTRA_T_mz_d2_m1_e2 +.MODEL LTRA_T_mz_d2_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 383 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 382 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 384 386 376 1 2.000000E+00 +E_m_pz_d2_m1_e2 386 1 380 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 385 387 378 1 2.000000E+00 +E_m_mz_d2_m1_e2 387 1 381 1 -1.000000E+00 +* +* DOMAIN 3 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d3_c1_e1 54 389 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d3_c1_m1_e1 389 1 388 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d3_c1_m1_e1 1 388 Vmeas_mode_decomp_d3_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d3_c1_e2 210 391 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d3_c1_m1_e2 391 1 390 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d3_c1_m1_e2 1 390 Vmeas_mode_decomp_d3_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d3_m1_e1 388 392 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d3_m1_e2 390 393 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d3_m1_e1 392 1 394 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d3_m1_e2 393 1 395 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d3_m1_e1 395 1 396 1 LTRA_T_pz_d3_m1_e1 +.MODEL LTRA_T_pz_d3_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d3_m1_e2 394 1 397 1 LTRA_T_mz_d3_m1_e2 +.MODEL LTRA_T_mz_d3_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d3_m1_e1 395 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d3_m1_e2 394 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d3_m1_e1 396 398 388 1 2.000000E+00 +E_m_pz_d3_m1_e2 398 1 392 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d3_m1_e1 397 399 390 1 2.000000E+00 +E_m_mz_d3_m1_e2 399 1 393 1 -1.000000E+00 +* +* DOMAIN 4 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d4_c1_e1 55 401 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d4_c1_m1_e1 401 1 400 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d4_c1_m1_e1 1 400 Vmeas_mode_decomp_d4_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d4_c1_e2 211 403 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d4_c1_m1_e2 403 1 402 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d4_c1_m1_e2 1 402 Vmeas_mode_decomp_d4_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d4_m1_e1 400 404 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d4_m1_e2 402 405 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d4_m1_e1 404 1 406 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d4_m1_e2 405 1 407 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d4_m1_e1 407 1 408 1 LTRA_T_pz_d4_m1_e1 +.MODEL LTRA_T_pz_d4_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d4_m1_e2 406 1 409 1 LTRA_T_mz_d4_m1_e2 +.MODEL LTRA_T_mz_d4_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d4_m1_e1 407 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d4_m1_e2 406 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d4_m1_e1 408 410 400 1 2.000000E+00 +E_m_pz_d4_m1_e2 410 1 404 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d4_m1_e1 409 411 402 1 2.000000E+00 +E_m_mz_d4_m1_e2 411 1 405 1 -1.000000E+00 +* +* DOMAIN 5 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d5_c1_e1 56 413 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d5_c1_m1_e1 413 1 412 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d5_c1_m1_e1 1 412 Vmeas_mode_decomp_d5_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d5_c1_e2 212 415 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d5_c1_m1_e2 415 1 414 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d5_c1_m1_e2 1 414 Vmeas_mode_decomp_d5_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d5_m1_e1 412 416 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d5_m1_e2 414 417 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d5_m1_e1 416 1 418 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d5_m1_e2 417 1 419 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d5_m1_e1 419 1 420 1 LTRA_T_pz_d5_m1_e1 +.MODEL LTRA_T_pz_d5_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d5_m1_e2 418 1 421 1 LTRA_T_mz_d5_m1_e2 +.MODEL LTRA_T_mz_d5_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d5_m1_e1 419 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d5_m1_e2 418 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d5_m1_e1 420 422 412 1 2.000000E+00 +E_m_pz_d5_m1_e2 422 1 416 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d5_m1_e1 421 423 414 1 2.000000E+00 +E_m_mz_d5_m1_e2 423 1 417 1 -1.000000E+00 +* +* DOMAIN 6 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d6_c1_e1 57 425 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d6_c1_m1_e1 425 1 424 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d6_c1_m1_e1 1 424 Vmeas_mode_decomp_d6_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d6_c1_e2 213 427 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d6_c1_m1_e2 427 1 426 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d6_c1_m1_e2 1 426 Vmeas_mode_decomp_d6_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d6_m1_e1 424 428 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d6_m1_e2 426 429 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d6_m1_e1 428 1 430 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d6_m1_e2 429 1 431 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d6_m1_e1 431 1 432 1 LTRA_T_pz_d6_m1_e1 +.MODEL LTRA_T_pz_d6_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d6_m1_e2 430 1 433 1 LTRA_T_mz_d6_m1_e2 +.MODEL LTRA_T_mz_d6_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d6_m1_e1 431 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d6_m1_e2 430 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d6_m1_e1 432 434 424 1 2.000000E+00 +E_m_pz_d6_m1_e2 434 1 428 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d6_m1_e1 433 435 426 1 2.000000E+00 +E_m_mz_d6_m1_e2 435 1 429 1 -1.000000E+00 +* +* DOMAIN 7 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d7_c1_e1 58 437 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d7_c1_m1_e1 437 1 436 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d7_c1_m1_e1 1 436 Vmeas_mode_decomp_d7_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d7_c1_e2 214 439 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d7_c1_m1_e2 439 1 438 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d7_c1_m1_e2 1 438 Vmeas_mode_decomp_d7_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d7_m1_e1 436 440 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d7_m1_e2 438 441 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d7_m1_e1 440 1 442 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d7_m1_e2 441 1 443 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d7_m1_e1 443 1 444 1 LTRA_T_pz_d7_m1_e1 +.MODEL LTRA_T_pz_d7_m1_e1 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d7_m1_e2 442 1 445 1 LTRA_T_mz_d7_m1_e2 +.MODEL LTRA_T_mz_d7_m1_e2 LTRA( R=0.0 L= 4.825545E-07 C= 3.381805E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d7_m1_e1 443 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d7_m1_e2 442 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d7_m1_e1 444 446 436 1 2.000000E+00 +E_m_pz_d7_m1_e2 446 1 440 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d7_m1_e1 445 447 438 1 2.000000E+00 +E_m_mz_d7_m1_e2 447 1 441 1 -1.000000E+00 +* +* DOMAIN 8 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d8_c1_e1 59 449 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d8_c1_m1_e1 449 1 448 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d8_c1_m1_e1 1 448 Vmeas_mode_decomp_d8_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d8_c1_e2 215 451 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d8_c1_m1_e2 451 1 450 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d8_c1_m1_e2 1 450 Vmeas_mode_decomp_d8_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d8_m1_e1 448 452 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d8_m1_e2 450 453 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d8_m1_e1 452 1 454 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d8_m1_e2 453 1 455 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d8_m1_e1 455 1 456 1 LTRA_T_pz_d8_m1_e1 +.MODEL LTRA_T_pz_d8_m1_e1 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d8_m1_e2 454 1 457 1 LTRA_T_mz_d8_m1_e2 +.MODEL LTRA_T_mz_d8_m1_e2 LTRA( R=0.0 L= 2.686772E-07 C= 4.822420E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d8_m1_e1 455 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d8_m1_e2 454 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d8_m1_e1 456 458 448 1 2.000000E+00 +E_m_pz_d8_m1_e2 458 1 452 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d8_m1_e1 457 459 450 1 2.000000E+00 +E_m_mz_d8_m1_e2 459 1 453 1 -1.000000E+00 +* +* DOMAIN 9 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d9_c1_e1 60 464 +Vmeas_mode_decomp_d9_c2_e1 61 468 +Vmeas_mode_decomp_d9_c3_e1 62 472 +Vmeas_mode_decomp_d9_c4_e1 63 476 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d9_c1_m1_e1 464 465 460 1 4.99997010E-01 +E_mode_decomp_d9_c1_m2_e1 465 466 461 1 6.60299603E-01 +E_mode_decomp_d9_c1_m3_e1 466 467 462 1 -2.52110920E-01 +E_mode_decomp_d9_c1_m4_e1 467 1 463 1 5.00566867E-01 +E_mode_decomp_d9_c2_m1_e1 468 469 460 1 5.00000814E-01 +E_mode_decomp_d9_c2_m2_e1 469 470 461 1 2.52638434E-01 +E_mode_decomp_d9_c2_m3_e1 470 471 462 1 6.60216363E-01 +E_mode_decomp_d9_c2_m4_e1 471 1 463 1 -5.00372583E-01 +E_mode_decomp_d9_c3_m1_e1 472 473 460 1 5.00001652E-01 +E_mode_decomp_d9_c3_m2_e1 473 474 461 1 -6.60745021E-01 +E_mode_decomp_d9_c3_m3_e1 474 475 462 1 2.52713880E-01 +E_mode_decomp_d9_c3_m4_e1 475 1 463 1 4.99437438E-01 +E_mode_decomp_d9_c4_m1_e1 476 477 460 1 5.00000524E-01 +E_mode_decomp_d9_c4_m2_e1 477 478 461 1 -2.52179072E-01 +E_mode_decomp_d9_c4_m3_e1 478 479 462 1 -6.60825366E-01 +E_mode_decomp_d9_c4_m4_e1 479 1 463 1 -4.99622234E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d9_c1_m1_e1 1 460 Vmeas_mode_decomp_d9_c1_e1 4.99997010E-01 +F_mode_decomp_d9_c2_m1_e1 1 460 Vmeas_mode_decomp_d9_c2_e1 5.00000814E-01 +F_mode_decomp_d9_c3_m1_e1 1 460 Vmeas_mode_decomp_d9_c3_e1 5.00001652E-01 +F_mode_decomp_d9_c4_m1_e1 1 460 Vmeas_mode_decomp_d9_c4_e1 5.00000524E-01 +F_mode_decomp_d9_c1_m2_e1 1 461 Vmeas_mode_decomp_d9_c1_e1 6.60299603E-01 +F_mode_decomp_d9_c2_m2_e1 1 461 Vmeas_mode_decomp_d9_c2_e1 2.52638434E-01 +F_mode_decomp_d9_c3_m2_e1 1 461 Vmeas_mode_decomp_d9_c3_e1 -6.60745021E-01 +F_mode_decomp_d9_c4_m2_e1 1 461 Vmeas_mode_decomp_d9_c4_e1 -2.52179072E-01 +F_mode_decomp_d9_c1_m3_e1 1 462 Vmeas_mode_decomp_d9_c1_e1 -2.52110920E-01 +F_mode_decomp_d9_c2_m3_e1 1 462 Vmeas_mode_decomp_d9_c2_e1 6.60216363E-01 +F_mode_decomp_d9_c3_m3_e1 1 462 Vmeas_mode_decomp_d9_c3_e1 2.52713880E-01 +F_mode_decomp_d9_c4_m3_e1 1 462 Vmeas_mode_decomp_d9_c4_e1 -6.60825366E-01 +F_mode_decomp_d9_c1_m4_e1 1 463 Vmeas_mode_decomp_d9_c1_e1 5.00566867E-01 +F_mode_decomp_d9_c2_m4_e1 1 463 Vmeas_mode_decomp_d9_c2_e1 -5.00372583E-01 +F_mode_decomp_d9_c3_m4_e1 1 463 Vmeas_mode_decomp_d9_c3_e1 4.99437438E-01 +F_mode_decomp_d9_c4_m4_e1 1 463 Vmeas_mode_decomp_d9_c4_e1 -4.99622234E-01 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d9_c1_e2 216 484 +Vmeas_mode_decomp_d9_c2_e2 217 488 +Vmeas_mode_decomp_d9_c3_e2 218 492 +Vmeas_mode_decomp_d9_c4_e2 219 496 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d9_c1_m1_e2 484 485 480 1 4.99997010E-01 +E_mode_decomp_d9_c1_m2_e2 485 486 481 1 6.60299603E-01 +E_mode_decomp_d9_c1_m3_e2 486 487 482 1 -2.52110920E-01 +E_mode_decomp_d9_c1_m4_e2 487 1 483 1 5.00566867E-01 +E_mode_decomp_d9_c2_m1_e2 488 489 480 1 5.00000814E-01 +E_mode_decomp_d9_c2_m2_e2 489 490 481 1 2.52638434E-01 +E_mode_decomp_d9_c2_m3_e2 490 491 482 1 6.60216363E-01 +E_mode_decomp_d9_c2_m4_e2 491 1 483 1 -5.00372583E-01 +E_mode_decomp_d9_c3_m1_e2 492 493 480 1 5.00001652E-01 +E_mode_decomp_d9_c3_m2_e2 493 494 481 1 -6.60745021E-01 +E_mode_decomp_d9_c3_m3_e2 494 495 482 1 2.52713880E-01 +E_mode_decomp_d9_c3_m4_e2 495 1 483 1 4.99437438E-01 +E_mode_decomp_d9_c4_m1_e2 496 497 480 1 5.00000524E-01 +E_mode_decomp_d9_c4_m2_e2 497 498 481 1 -2.52179072E-01 +E_mode_decomp_d9_c4_m3_e2 498 499 482 1 -6.60825366E-01 +E_mode_decomp_d9_c4_m4_e2 499 1 483 1 -4.99622234E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d9_c1_m1_e2 1 480 Vmeas_mode_decomp_d9_c1_e2 4.99997010E-01 +F_mode_decomp_d9_c2_m1_e2 1 480 Vmeas_mode_decomp_d9_c2_e2 5.00000814E-01 +F_mode_decomp_d9_c3_m1_e2 1 480 Vmeas_mode_decomp_d9_c3_e2 5.00001652E-01 +F_mode_decomp_d9_c4_m1_e2 1 480 Vmeas_mode_decomp_d9_c4_e2 5.00000524E-01 +F_mode_decomp_d9_c1_m2_e2 1 481 Vmeas_mode_decomp_d9_c1_e2 6.60299603E-01 +F_mode_decomp_d9_c2_m2_e2 1 481 Vmeas_mode_decomp_d9_c2_e2 2.52638434E-01 +F_mode_decomp_d9_c3_m2_e2 1 481 Vmeas_mode_decomp_d9_c3_e2 -6.60745021E-01 +F_mode_decomp_d9_c4_m2_e2 1 481 Vmeas_mode_decomp_d9_c4_e2 -2.52179072E-01 +F_mode_decomp_d9_c1_m3_e2 1 482 Vmeas_mode_decomp_d9_c1_e2 -2.52110920E-01 +F_mode_decomp_d9_c2_m3_e2 1 482 Vmeas_mode_decomp_d9_c2_e2 6.60216363E-01 +F_mode_decomp_d9_c3_m3_e2 1 482 Vmeas_mode_decomp_d9_c3_e2 2.52713880E-01 +F_mode_decomp_d9_c4_m3_e2 1 482 Vmeas_mode_decomp_d9_c4_e2 -6.60825366E-01 +F_mode_decomp_d9_c1_m4_e2 1 483 Vmeas_mode_decomp_d9_c1_e2 5.00566867E-01 +F_mode_decomp_d9_c2_m4_e2 1 483 Vmeas_mode_decomp_d9_c2_e2 -5.00372583E-01 +F_mode_decomp_d9_c3_m4_e2 1 483 Vmeas_mode_decomp_d9_c3_e2 4.99437438E-01 +F_mode_decomp_d9_c4_m4_e2 1 483 Vmeas_mode_decomp_d9_c4_e2 -4.99622234E-01 +* +* Modal impedance: end1 +* +RZCm_d9_m1_e1 460 500 9.322448E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m1_e2 480 501 9.322448E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m1_e1 500 1 502 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m1_e2 501 1 503 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m1_e1 503 1 504 1 LTRA_T_pz_d9_m1_e1 +.MODEL LTRA_T_pz_d9_m1_e1 LTRA( R=0.0 L= 3.236033E-07 C= 3.723514E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m1_e2 502 1 505 1 LTRA_T_mz_d9_m1_e2 +.MODEL LTRA_T_mz_d9_m1_e2 LTRA( R=0.0 L= 3.236033E-07 C= 3.723514E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m1_e1 503 1 9.322448E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m1_e2 502 1 9.322448E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m1_e1 504 506 460 1 2.000000E+00 +E_m_pz_d9_m1_e2 506 1 500 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m1_e1 505 507 480 1 2.000000E+00 +E_m_mz_d9_m1_e2 507 1 501 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m2_e1 461 508 4.294265E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m2_e2 481 509 4.294265E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m2_e1 508 1 510 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m2_e2 509 1 511 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m2_e1 511 1 512 1 LTRA_T_pz_d9_m2_e1 +.MODEL LTRA_T_pz_d9_m2_e1 LTRA( R=0.0 L= 1.530171E-07 C= 8.297789E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m2_e2 510 1 513 1 LTRA_T_mz_d9_m2_e2 +.MODEL LTRA_T_mz_d9_m2_e2 LTRA( R=0.0 L= 1.530171E-07 C= 8.297789E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m2_e1 511 1 4.294265E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m2_e2 510 1 4.294265E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m2_e1 512 514 461 1 2.000000E+00 +E_m_pz_d9_m2_e2 514 1 508 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m2_e1 513 515 481 1 2.000000E+00 +E_m_mz_d9_m2_e2 515 1 509 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m3_e1 462 516 4.294177E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m3_e2 482 517 4.294177E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m3_e1 516 1 518 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m3_e2 517 1 519 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m3_e1 519 1 520 1 LTRA_T_pz_d9_m3_e1 +.MODEL LTRA_T_pz_d9_m3_e1 LTRA( R=0.0 L= 1.530143E-07 C= 8.297977E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m3_e2 518 1 521 1 LTRA_T_mz_d9_m3_e2 +.MODEL LTRA_T_mz_d9_m3_e2 LTRA( R=0.0 L= 1.530143E-07 C= 8.297977E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m3_e1 519 1 4.294177E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m3_e2 518 1 4.294177E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m3_e1 520 522 462 1 2.000000E+00 +E_m_pz_d9_m3_e2 522 1 516 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m3_e1 521 523 482 1 2.000000E+00 +E_m_mz_d9_m3_e2 523 1 517 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m4_e1 463 524 2.983334E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m4_e2 483 525 2.983334E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m4_e1 524 1 526 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m4_e2 525 1 527 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d9_m4_e1 527 1 528 1 LTRA_T_pz_d9_m4_e1 +.MODEL LTRA_T_pz_d9_m4_e1 LTRA( R=0.0 L= 1.076602E-07 C= 1.209627E-10 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d9_m4_e2 526 1 529 1 LTRA_T_mz_d9_m4_e2 +.MODEL LTRA_T_mz_d9_m4_e2 LTRA( R=0.0 L= 1.076602E-07 C= 1.209627E-10 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m4_e1 527 1 2.983334E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m4_e2 526 1 2.983334E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m4_e1 528 530 463 1 2.000000E+00 +E_m_pz_d9_m4_e2 530 1 524 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m4_e1 529 531 483 1 2.000000E+00 +E_m_mz_d9_m4_e2 531 1 525 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_PSpice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_PSpice.lib new file mode 100644 index 0000000..16fe1b0 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Spacewire_PSpice.lib @@ -0,0 +1,1568 @@ +* Pspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 +* node: 3 Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 +* node: 4 Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 +* node: 5 Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 +* node: 6 Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 +* node: 7 Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 +* node: 8 Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 +* node: 9 Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 +* node: 10 Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 +* node: 11 Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 +* node: 12 Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 +* node: 13 Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 +* node: 14 Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield +* +* End 2 nodes: +* +* node: 15 Conductor number 1. Cable name: spacewire. type: spacewire. conductor 1 : Twisted pair 1 wire 1 +* node: 16 Conductor number 2. Cable name: spacewire. type: spacewire. conductor 2 : Twisted pair 1 wire 2 +* node: 17 Conductor number 3. Cable name: spacewire. type: spacewire. conductor 3 : Twisted pair 2 wire 1 +* node: 18 Conductor number 4. Cable name: spacewire. type: spacewire. conductor 4 : Twisted pair 2 wire 2 +* node: 19 Conductor number 5. Cable name: spacewire. type: spacewire. conductor 5 : Twisted pair 3 wire 1 +* node: 20 Conductor number 6. Cable name: spacewire. type: spacewire. conductor 6 : Twisted pair 3 wire 2 +* node: 21 Conductor number 7. Cable name: spacewire. type: spacewire. conductor 7 : Twisted pair 4 wire 1 +* node: 22 Conductor number 8. Cable name: spacewire. type: spacewire. conductor 8 : Twisted pair 4 wire 2 +* node: 23 Conductor number 9. Cable name: spacewire. type: spacewire. conductor 9 : Inner Shield 1 +* node: 24 Conductor number 10. Cable name: spacewire. type: spacewire. conductor 10: Inner Shield 2 +* node: 25 Conductor number 11. Cable name: spacewire. type: spacewire. conductor 11: Inner Shield 3 +* node: 26 Conductor number 12. Cable name: spacewire. type: spacewire. conductor 12: Inner Shield 4 +* node: 27 Conductor number 13. Cable name: spacewire. type: spacewire. conductor 13: Outer Shield +* +.subckt ZT_FD_Spacewire ++ 2 3 4 5 6 7 8 9 10 11 12 13 14 ++ 15 16 17 18 19 20 21 22 23 24 25 26 27 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 28 5.092958E-02 +Rdc_c2_e1 3 29 5.092958E-02 +Rdc_c3_e1 4 30 5.092958E-02 +Rdc_c4_e1 5 31 5.092958E-02 +Rdc_c5_e1 6 32 5.092958E-02 +Rdc_c6_e1 7 33 5.092958E-02 +Rdc_c7_e1 8 34 5.092958E-02 +Rdc_c8_e1 9 35 5.092958E-02 +Rdc_c9_e1 10 36 1.273240E-02 +Rdc_c10_e1 11 37 1.273240E-02 +Rdc_c11_e1 12 38 1.273240E-02 +Rdc_c12_e1 13 39 1.273240E-02 +Rdc_c13_e1 14 1 3.395291E-03 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 15 40 5.092958E-02 +Rdc_c2_e2 16 41 5.092958E-02 +Rdc_c3_e2 17 42 5.092958E-02 +Rdc_c4_e2 18 43 5.092958E-02 +Rdc_c5_e2 19 44 5.092958E-02 +Rdc_c6_e2 20 45 5.092958E-02 +Rdc_c7_e2 21 46 5.092958E-02 +Rdc_c8_e2 22 47 5.092958E-02 +Rdc_c9_e2 23 48 1.273240E-02 +Rdc_c10_e2 24 49 1.273240E-02 +Rdc_c11_e2 25 50 1.273240E-02 +Rdc_c12_e2 26 51 1.273240E-02 +Rdc_c13_e2 27 1 3.395291E-03 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 28 64 +Vmeas_domain_decomp_c2_e1 29 76 +Vmeas_domain_decomp_c3_e1 30 88 +Vmeas_domain_decomp_c4_e1 31 100 +Vmeas_domain_decomp_c5_e1 32 112 +Vmeas_domain_decomp_c6_e1 33 124 +Vmeas_domain_decomp_c7_e1 34 136 +Vmeas_domain_decomp_c8_e1 35 148 +Vmeas_domain_decomp_c9_e1 36 160 +Vmeas_domain_decomp_c10_e1 37 172 +Vmeas_domain_decomp_c11_e1 38 184 +Vmeas_domain_decomp_c12_e1 39 196 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 64 65 52 1 5.000000E-01 +E_domain_decomp_c1_dc2_e1 65 66 53 1 1.000000E+00 +E_domain_decomp_c1_dc3_e1 66 67 54 1 0.000000E+00 +E_domain_decomp_c1_dc4_e1 67 68 55 1 0.000000E+00 +E_domain_decomp_c1_dc5_e1 68 69 56 1 0.000000E+00 +E_domain_decomp_c1_dc6_e1 69 70 57 1 0.000000E+00 +E_domain_decomp_c1_dc7_e1 70 71 58 1 0.000000E+00 +E_domain_decomp_c1_dc8_e1 71 72 59 1 -0.000000E+00 +E_domain_decomp_c1_dc9_e1 72 73 60 1 1.000000E+00 +E_domain_decomp_c1_dc10_e1 73 74 61 1 0.000000E+00 +E_domain_decomp_c1_dc11_e1 74 75 62 1 0.000000E+00 +E_domain_decomp_c1_dc12_e1 75 1 63 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e1 76 77 52 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e1 77 78 53 1 1.000000E+00 +E_domain_decomp_c2_dc3_e1 78 79 54 1 0.000000E+00 +E_domain_decomp_c2_dc4_e1 79 80 55 1 0.000000E+00 +E_domain_decomp_c2_dc5_e1 80 81 56 1 0.000000E+00 +E_domain_decomp_c2_dc6_e1 81 82 57 1 0.000000E+00 +E_domain_decomp_c2_dc7_e1 82 83 58 1 0.000000E+00 +E_domain_decomp_c2_dc8_e1 83 84 59 1 -0.000000E+00 +E_domain_decomp_c2_dc9_e1 84 85 60 1 1.000000E+00 +E_domain_decomp_c2_dc10_e1 85 86 61 1 0.000000E+00 +E_domain_decomp_c2_dc11_e1 86 87 62 1 0.000000E+00 +E_domain_decomp_c2_dc12_e1 87 1 63 1 -0.000000E+00 +E_domain_decomp_c3_dc1_e1 88 89 52 1 0.000000E+00 +E_domain_decomp_c3_dc2_e1 89 90 53 1 0.000000E+00 +E_domain_decomp_c3_dc3_e1 90 91 54 1 5.000000E-01 +E_domain_decomp_c3_dc4_e1 91 92 55 1 1.000000E+00 +E_domain_decomp_c3_dc5_e1 92 93 56 1 0.000000E+00 +E_domain_decomp_c3_dc6_e1 93 94 57 1 0.000000E+00 +E_domain_decomp_c3_dc7_e1 94 95 58 1 0.000000E+00 +E_domain_decomp_c3_dc8_e1 95 96 59 1 0.000000E+00 +E_domain_decomp_c3_dc9_e1 96 97 60 1 -0.000000E+00 +E_domain_decomp_c3_dc10_e1 97 98 61 1 1.000000E+00 +E_domain_decomp_c3_dc11_e1 98 99 62 1 0.000000E+00 +E_domain_decomp_c3_dc12_e1 99 1 63 1 -0.000000E+00 +E_domain_decomp_c4_dc1_e1 100 101 52 1 0.000000E+00 +E_domain_decomp_c4_dc2_e1 101 102 53 1 0.000000E+00 +E_domain_decomp_c4_dc3_e1 102 103 54 1 -5.000000E-01 +E_domain_decomp_c4_dc4_e1 103 104 55 1 1.000000E+00 +E_domain_decomp_c4_dc5_e1 104 105 56 1 0.000000E+00 +E_domain_decomp_c4_dc6_e1 105 106 57 1 0.000000E+00 +E_domain_decomp_c4_dc7_e1 106 107 58 1 0.000000E+00 +E_domain_decomp_c4_dc8_e1 107 108 59 1 0.000000E+00 +E_domain_decomp_c4_dc9_e1 108 109 60 1 -0.000000E+00 +E_domain_decomp_c4_dc10_e1 109 110 61 1 1.000000E+00 +E_domain_decomp_c4_dc11_e1 110 111 62 1 0.000000E+00 +E_domain_decomp_c4_dc12_e1 111 1 63 1 -0.000000E+00 +E_domain_decomp_c5_dc1_e1 112 113 52 1 0.000000E+00 +E_domain_decomp_c5_dc2_e1 113 114 53 1 0.000000E+00 +E_domain_decomp_c5_dc3_e1 114 115 54 1 0.000000E+00 +E_domain_decomp_c5_dc4_e1 115 116 55 1 0.000000E+00 +E_domain_decomp_c5_dc5_e1 116 117 56 1 5.000000E-01 +E_domain_decomp_c5_dc6_e1 117 118 57 1 1.000000E+00 +E_domain_decomp_c5_dc7_e1 118 119 58 1 0.000000E+00 +E_domain_decomp_c5_dc8_e1 119 120 59 1 0.000000E+00 +E_domain_decomp_c5_dc9_e1 120 121 60 1 0.000000E+00 +E_domain_decomp_c5_dc10_e1 121 122 61 1 -0.000000E+00 +E_domain_decomp_c5_dc11_e1 122 123 62 1 1.000000E+00 +E_domain_decomp_c5_dc12_e1 123 1 63 1 -0.000000E+00 +E_domain_decomp_c6_dc1_e1 124 125 52 1 0.000000E+00 +E_domain_decomp_c6_dc2_e1 125 126 53 1 0.000000E+00 +E_domain_decomp_c6_dc3_e1 126 127 54 1 0.000000E+00 +E_domain_decomp_c6_dc4_e1 127 128 55 1 0.000000E+00 +E_domain_decomp_c6_dc5_e1 128 129 56 1 -5.000000E-01 +E_domain_decomp_c6_dc6_e1 129 130 57 1 1.000000E+00 +E_domain_decomp_c6_dc7_e1 130 131 58 1 0.000000E+00 +E_domain_decomp_c6_dc8_e1 131 132 59 1 0.000000E+00 +E_domain_decomp_c6_dc9_e1 132 133 60 1 0.000000E+00 +E_domain_decomp_c6_dc10_e1 133 134 61 1 -0.000000E+00 +E_domain_decomp_c6_dc11_e1 134 135 62 1 1.000000E+00 +E_domain_decomp_c6_dc12_e1 135 1 63 1 -0.000000E+00 +E_domain_decomp_c7_dc1_e1 136 137 52 1 0.000000E+00 +E_domain_decomp_c7_dc2_e1 137 138 53 1 0.000000E+00 +E_domain_decomp_c7_dc3_e1 138 139 54 1 0.000000E+00 +E_domain_decomp_c7_dc4_e1 139 140 55 1 0.000000E+00 +E_domain_decomp_c7_dc5_e1 140 141 56 1 0.000000E+00 +E_domain_decomp_c7_dc6_e1 141 142 57 1 0.000000E+00 +E_domain_decomp_c7_dc7_e1 142 143 58 1 5.000000E-01 +E_domain_decomp_c7_dc8_e1 143 144 59 1 1.000000E+00 +E_domain_decomp_c7_dc9_e1 144 145 60 1 0.000000E+00 +E_domain_decomp_c7_dc10_e1 145 146 61 1 0.000000E+00 +E_domain_decomp_c7_dc11_e1 146 147 62 1 -0.000000E+00 +E_domain_decomp_c7_dc12_e1 147 1 63 1 1.000000E+00 +E_domain_decomp_c8_dc1_e1 148 149 52 1 0.000000E+00 +E_domain_decomp_c8_dc2_e1 149 150 53 1 0.000000E+00 +E_domain_decomp_c8_dc3_e1 150 151 54 1 0.000000E+00 +E_domain_decomp_c8_dc4_e1 151 152 55 1 0.000000E+00 +E_domain_decomp_c8_dc5_e1 152 153 56 1 0.000000E+00 +E_domain_decomp_c8_dc6_e1 153 154 57 1 0.000000E+00 +E_domain_decomp_c8_dc7_e1 154 155 58 1 -5.000000E-01 +E_domain_decomp_c8_dc8_e1 155 156 59 1 1.000000E+00 +E_domain_decomp_c8_dc9_e1 156 157 60 1 0.000000E+00 +E_domain_decomp_c8_dc10_e1 157 158 61 1 0.000000E+00 +E_domain_decomp_c8_dc11_e1 158 159 62 1 -0.000000E+00 +E_domain_decomp_c8_dc12_e1 159 1 63 1 1.000000E+00 +E_domain_decomp_c9_dc1_e1 160 161 52 1 0.000000E+00 +E_domain_decomp_c9_dc2_e1 161 162 53 1 0.000000E+00 +E_domain_decomp_c9_dc3_e1 162 163 54 1 0.000000E+00 +E_domain_decomp_c9_dc4_e1 163 164 55 1 0.000000E+00 +E_domain_decomp_c9_dc5_e1 164 165 56 1 0.000000E+00 +E_domain_decomp_c9_dc6_e1 165 166 57 1 0.000000E+00 +E_domain_decomp_c9_dc7_e1 166 167 58 1 0.000000E+00 +E_domain_decomp_c9_dc8_e1 167 168 59 1 -0.000000E+00 +E_domain_decomp_c9_dc9_e1 168 169 60 1 1.000000E+00 +E_domain_decomp_c9_dc10_e1 169 170 61 1 0.000000E+00 +E_domain_decomp_c9_dc11_e1 170 171 62 1 0.000000E+00 +E_domain_decomp_c9_dc12_e1 171 1 63 1 -0.000000E+00 +E_domain_decomp_c10_dc1_e1 172 173 52 1 0.000000E+00 +E_domain_decomp_c10_dc2_e1 173 174 53 1 0.000000E+00 +E_domain_decomp_c10_dc3_e1 174 175 54 1 0.000000E+00 +E_domain_decomp_c10_dc4_e1 175 176 55 1 0.000000E+00 +E_domain_decomp_c10_dc5_e1 176 177 56 1 0.000000E+00 +E_domain_decomp_c10_dc6_e1 177 178 57 1 0.000000E+00 +E_domain_decomp_c10_dc7_e1 178 179 58 1 0.000000E+00 +E_domain_decomp_c10_dc8_e1 179 180 59 1 0.000000E+00 +E_domain_decomp_c10_dc9_e1 180 181 60 1 -0.000000E+00 +E_domain_decomp_c10_dc10_e1 181 182 61 1 1.000000E+00 +E_domain_decomp_c10_dc11_e1 182 183 62 1 0.000000E+00 +E_domain_decomp_c10_dc12_e1 183 1 63 1 -0.000000E+00 +E_domain_decomp_c11_dc1_e1 184 185 52 1 0.000000E+00 +E_domain_decomp_c11_dc2_e1 185 186 53 1 0.000000E+00 +E_domain_decomp_c11_dc3_e1 186 187 54 1 0.000000E+00 +E_domain_decomp_c11_dc4_e1 187 188 55 1 0.000000E+00 +E_domain_decomp_c11_dc5_e1 188 189 56 1 0.000000E+00 +E_domain_decomp_c11_dc6_e1 189 190 57 1 0.000000E+00 +E_domain_decomp_c11_dc7_e1 190 191 58 1 0.000000E+00 +E_domain_decomp_c11_dc8_e1 191 192 59 1 0.000000E+00 +E_domain_decomp_c11_dc9_e1 192 193 60 1 0.000000E+00 +E_domain_decomp_c11_dc10_e1 193 194 61 1 -0.000000E+00 +E_domain_decomp_c11_dc11_e1 194 195 62 1 1.000000E+00 +E_domain_decomp_c11_dc12_e1 195 1 63 1 -0.000000E+00 +E_domain_decomp_c12_dc1_e1 196 197 52 1 0.000000E+00 +E_domain_decomp_c12_dc2_e1 197 198 53 1 0.000000E+00 +E_domain_decomp_c12_dc3_e1 198 199 54 1 0.000000E+00 +E_domain_decomp_c12_dc4_e1 199 200 55 1 0.000000E+00 +E_domain_decomp_c12_dc5_e1 200 201 56 1 0.000000E+00 +E_domain_decomp_c12_dc6_e1 201 202 57 1 0.000000E+00 +E_domain_decomp_c12_dc7_e1 202 203 58 1 0.000000E+00 +E_domain_decomp_c12_dc8_e1 203 204 59 1 0.000000E+00 +E_domain_decomp_c12_dc9_e1 204 205 60 1 0.000000E+00 +E_domain_decomp_c12_dc10_e1 205 206 61 1 0.000000E+00 +E_domain_decomp_c12_dc11_e1 206 207 62 1 -0.000000E+00 +E_domain_decomp_c12_dc12_e1 207 1 63 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 52 Vmeas_domain_decomp_c1_e1 5.000000E-01 +F_domain_decomp_c2_dc1_e1 1 52 Vmeas_domain_decomp_c2_e1 -5.000000E-01 +F_domain_decomp_c3_dc1_e1 1 52 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc1_e1 1 52 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc1_e1 1 52 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc1_e1 1 52 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc1_e1 1 52 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc1_e1 1 52 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc1_e1 1 52 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc1_e1 1 52 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc1_e1 1 52 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc1_e1 1 52 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 53 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc2_e1 1 53 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c3_dc2_e1 1 53 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc2_e1 1 53 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc2_e1 1 53 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc2_e1 1 53 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc2_e1 1 53 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc2_e1 1 53 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc2_e1 1 53 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc2_e1 1 53 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc2_e1 1 53 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc2_e1 1 53 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc3_e1 1 54 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc3_e1 1 54 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc3_e1 1 54 Vmeas_domain_decomp_c3_e1 5.000000E-01 +F_domain_decomp_c4_dc3_e1 1 54 Vmeas_domain_decomp_c4_e1 -5.000000E-01 +F_domain_decomp_c5_dc3_e1 1 54 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc3_e1 1 54 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc3_e1 1 54 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc3_e1 1 54 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc3_e1 1 54 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc3_e1 1 54 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc3_e1 1 54 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc3_e1 1 54 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc4_e1 1 55 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc4_e1 1 55 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc4_e1 1 55 Vmeas_domain_decomp_c3_e1 1.000000E+00 +F_domain_decomp_c4_dc4_e1 1 55 Vmeas_domain_decomp_c4_e1 1.000000E+00 +F_domain_decomp_c5_dc4_e1 1 55 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc4_e1 1 55 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc4_e1 1 55 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc4_e1 1 55 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc4_e1 1 55 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc4_e1 1 55 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc4_e1 1 55 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc4_e1 1 55 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc5_e1 1 56 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc5_e1 1 56 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc5_e1 1 56 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc5_e1 1 56 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc5_e1 1 56 Vmeas_domain_decomp_c5_e1 5.000000E-01 +F_domain_decomp_c6_dc5_e1 1 56 Vmeas_domain_decomp_c6_e1 -5.000000E-01 +F_domain_decomp_c7_dc5_e1 1 56 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc5_e1 1 56 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc5_e1 1 56 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc5_e1 1 56 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc5_e1 1 56 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc5_e1 1 56 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc6_e1 1 57 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc6_e1 1 57 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc6_e1 1 57 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc6_e1 1 57 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc6_e1 1 57 Vmeas_domain_decomp_c5_e1 1.000000E+00 +F_domain_decomp_c6_dc6_e1 1 57 Vmeas_domain_decomp_c6_e1 1.000000E+00 +F_domain_decomp_c7_dc6_e1 1 57 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc6_e1 1 57 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc6_e1 1 57 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc6_e1 1 57 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc6_e1 1 57 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc6_e1 1 57 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc7_e1 1 58 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc7_e1 1 58 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc7_e1 1 58 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc7_e1 1 58 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc7_e1 1 58 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc7_e1 1 58 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc7_e1 1 58 Vmeas_domain_decomp_c7_e1 5.000000E-01 +F_domain_decomp_c8_dc7_e1 1 58 Vmeas_domain_decomp_c8_e1 -5.000000E-01 +F_domain_decomp_c9_dc7_e1 1 58 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc7_e1 1 58 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc7_e1 1 58 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc7_e1 1 58 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc8_e1 1 59 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc8_e1 1 59 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc8_e1 1 59 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc8_e1 1 59 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc8_e1 1 59 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc8_e1 1 59 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc8_e1 1 59 Vmeas_domain_decomp_c7_e1 1.000000E+00 +F_domain_decomp_c8_dc8_e1 1 59 Vmeas_domain_decomp_c8_e1 1.000000E+00 +F_domain_decomp_c9_dc8_e1 1 59 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc8_e1 1 59 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc8_e1 1 59 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc8_e1 1 59 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc9_e1 1 60 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc9_e1 1 60 Vmeas_domain_decomp_c2_e1 1.000000E+00 +F_domain_decomp_c3_dc9_e1 1 60 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc9_e1 1 60 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc9_e1 1 60 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc9_e1 1 60 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc9_e1 1 60 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc9_e1 1 60 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc9_e1 1 60 Vmeas_domain_decomp_c9_e1 1.000000E+00 +F_domain_decomp_c10_dc9_e1 1 60 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc9_e1 1 60 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc9_e1 1 60 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc10_e1 1 61 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc10_e1 1 61 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc10_e1 1 61 Vmeas_domain_decomp_c3_e1 1.000000E+00 +F_domain_decomp_c4_dc10_e1 1 61 Vmeas_domain_decomp_c4_e1 1.000000E+00 +F_domain_decomp_c5_dc10_e1 1 61 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc10_e1 1 61 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc10_e1 1 61 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc10_e1 1 61 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc10_e1 1 61 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc10_e1 1 61 Vmeas_domain_decomp_c10_e1 1.000000E+00 +F_domain_decomp_c11_dc10_e1 1 61 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc10_e1 1 61 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc11_e1 1 62 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc11_e1 1 62 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc11_e1 1 62 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc11_e1 1 62 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc11_e1 1 62 Vmeas_domain_decomp_c5_e1 1.000000E+00 +F_domain_decomp_c6_dc11_e1 1 62 Vmeas_domain_decomp_c6_e1 1.000000E+00 +F_domain_decomp_c7_dc11_e1 1 62 Vmeas_domain_decomp_c7_e1 0.000000E+00 +F_domain_decomp_c8_dc11_e1 1 62 Vmeas_domain_decomp_c8_e1 0.000000E+00 +F_domain_decomp_c9_dc11_e1 1 62 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc11_e1 1 62 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc11_e1 1 62 Vmeas_domain_decomp_c11_e1 1.000000E+00 +F_domain_decomp_c12_dc11_e1 1 62 Vmeas_domain_decomp_c12_e1 0.000000E+00 +F_domain_decomp_c1_dc12_e1 1 63 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc12_e1 1 63 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c3_dc12_e1 1 63 Vmeas_domain_decomp_c3_e1 0.000000E+00 +F_domain_decomp_c4_dc12_e1 1 63 Vmeas_domain_decomp_c4_e1 0.000000E+00 +F_domain_decomp_c5_dc12_e1 1 63 Vmeas_domain_decomp_c5_e1 0.000000E+00 +F_domain_decomp_c6_dc12_e1 1 63 Vmeas_domain_decomp_c6_e1 0.000000E+00 +F_domain_decomp_c7_dc12_e1 1 63 Vmeas_domain_decomp_c7_e1 1.000000E+00 +F_domain_decomp_c8_dc12_e1 1 63 Vmeas_domain_decomp_c8_e1 1.000000E+00 +F_domain_decomp_c9_dc12_e1 1 63 Vmeas_domain_decomp_c9_e1 0.000000E+00 +F_domain_decomp_c10_dc12_e1 1 63 Vmeas_domain_decomp_c10_e1 0.000000E+00 +F_domain_decomp_c11_dc12_e1 1 63 Vmeas_domain_decomp_c11_e1 0.000000E+00 +F_domain_decomp_c12_dc12_e1 1 63 Vmeas_domain_decomp_c12_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 40 220 +Vmeas_domain_decomp_c2_e2 41 232 +Vmeas_domain_decomp_c3_e2 42 244 +Vmeas_domain_decomp_c4_e2 43 256 +Vmeas_domain_decomp_c5_e2 44 268 +Vmeas_domain_decomp_c6_e2 45 280 +Vmeas_domain_decomp_c7_e2 46 292 +Vmeas_domain_decomp_c8_e2 47 304 +Vmeas_domain_decomp_c9_e2 48 316 +Vmeas_domain_decomp_c10_e2 49 328 +Vmeas_domain_decomp_c11_e2 50 340 +Vmeas_domain_decomp_c12_e2 51 352 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 220 221 208 1 5.000000E-01 +E_domain_decomp_c1_dc2_e2 221 222 209 1 1.000000E+00 +E_domain_decomp_c1_dc3_e2 222 223 210 1 0.000000E+00 +E_domain_decomp_c1_dc4_e2 223 224 211 1 0.000000E+00 +E_domain_decomp_c1_dc5_e2 224 225 212 1 0.000000E+00 +E_domain_decomp_c1_dc6_e2 225 226 213 1 0.000000E+00 +E_domain_decomp_c1_dc7_e2 226 227 214 1 0.000000E+00 +E_domain_decomp_c1_dc8_e2 227 228 215 1 -0.000000E+00 +E_domain_decomp_c1_dc9_e2 228 229 216 1 1.000000E+00 +E_domain_decomp_c1_dc10_e2 229 230 217 1 0.000000E+00 +E_domain_decomp_c1_dc11_e2 230 231 218 1 0.000000E+00 +E_domain_decomp_c1_dc12_e2 231 1 219 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e2 232 233 208 1 -5.000000E-01 +E_domain_decomp_c2_dc2_e2 233 234 209 1 1.000000E+00 +E_domain_decomp_c2_dc3_e2 234 235 210 1 0.000000E+00 +E_domain_decomp_c2_dc4_e2 235 236 211 1 0.000000E+00 +E_domain_decomp_c2_dc5_e2 236 237 212 1 0.000000E+00 +E_domain_decomp_c2_dc6_e2 237 238 213 1 0.000000E+00 +E_domain_decomp_c2_dc7_e2 238 239 214 1 0.000000E+00 +E_domain_decomp_c2_dc8_e2 239 240 215 1 -0.000000E+00 +E_domain_decomp_c2_dc9_e2 240 241 216 1 1.000000E+00 +E_domain_decomp_c2_dc10_e2 241 242 217 1 0.000000E+00 +E_domain_decomp_c2_dc11_e2 242 243 218 1 0.000000E+00 +E_domain_decomp_c2_dc12_e2 243 1 219 1 -0.000000E+00 +E_domain_decomp_c3_dc1_e2 244 245 208 1 0.000000E+00 +E_domain_decomp_c3_dc2_e2 245 246 209 1 0.000000E+00 +E_domain_decomp_c3_dc3_e2 246 247 210 1 5.000000E-01 +E_domain_decomp_c3_dc4_e2 247 248 211 1 1.000000E+00 +E_domain_decomp_c3_dc5_e2 248 249 212 1 0.000000E+00 +E_domain_decomp_c3_dc6_e2 249 250 213 1 0.000000E+00 +E_domain_decomp_c3_dc7_e2 250 251 214 1 0.000000E+00 +E_domain_decomp_c3_dc8_e2 251 252 215 1 0.000000E+00 +E_domain_decomp_c3_dc9_e2 252 253 216 1 -0.000000E+00 +E_domain_decomp_c3_dc10_e2 253 254 217 1 1.000000E+00 +E_domain_decomp_c3_dc11_e2 254 255 218 1 0.000000E+00 +E_domain_decomp_c3_dc12_e2 255 1 219 1 -0.000000E+00 +E_domain_decomp_c4_dc1_e2 256 257 208 1 0.000000E+00 +E_domain_decomp_c4_dc2_e2 257 258 209 1 0.000000E+00 +E_domain_decomp_c4_dc3_e2 258 259 210 1 -5.000000E-01 +E_domain_decomp_c4_dc4_e2 259 260 211 1 1.000000E+00 +E_domain_decomp_c4_dc5_e2 260 261 212 1 0.000000E+00 +E_domain_decomp_c4_dc6_e2 261 262 213 1 0.000000E+00 +E_domain_decomp_c4_dc7_e2 262 263 214 1 0.000000E+00 +E_domain_decomp_c4_dc8_e2 263 264 215 1 0.000000E+00 +E_domain_decomp_c4_dc9_e2 264 265 216 1 -0.000000E+00 +E_domain_decomp_c4_dc10_e2 265 266 217 1 1.000000E+00 +E_domain_decomp_c4_dc11_e2 266 267 218 1 0.000000E+00 +E_domain_decomp_c4_dc12_e2 267 1 219 1 -0.000000E+00 +E_domain_decomp_c5_dc1_e2 268 269 208 1 0.000000E+00 +E_domain_decomp_c5_dc2_e2 269 270 209 1 0.000000E+00 +E_domain_decomp_c5_dc3_e2 270 271 210 1 0.000000E+00 +E_domain_decomp_c5_dc4_e2 271 272 211 1 0.000000E+00 +E_domain_decomp_c5_dc5_e2 272 273 212 1 5.000000E-01 +E_domain_decomp_c5_dc6_e2 273 274 213 1 1.000000E+00 +E_domain_decomp_c5_dc7_e2 274 275 214 1 0.000000E+00 +E_domain_decomp_c5_dc8_e2 275 276 215 1 0.000000E+00 +E_domain_decomp_c5_dc9_e2 276 277 216 1 0.000000E+00 +E_domain_decomp_c5_dc10_e2 277 278 217 1 -0.000000E+00 +E_domain_decomp_c5_dc11_e2 278 279 218 1 1.000000E+00 +E_domain_decomp_c5_dc12_e2 279 1 219 1 -0.000000E+00 +E_domain_decomp_c6_dc1_e2 280 281 208 1 0.000000E+00 +E_domain_decomp_c6_dc2_e2 281 282 209 1 0.000000E+00 +E_domain_decomp_c6_dc3_e2 282 283 210 1 0.000000E+00 +E_domain_decomp_c6_dc4_e2 283 284 211 1 0.000000E+00 +E_domain_decomp_c6_dc5_e2 284 285 212 1 -5.000000E-01 +E_domain_decomp_c6_dc6_e2 285 286 213 1 1.000000E+00 +E_domain_decomp_c6_dc7_e2 286 287 214 1 0.000000E+00 +E_domain_decomp_c6_dc8_e2 287 288 215 1 0.000000E+00 +E_domain_decomp_c6_dc9_e2 288 289 216 1 0.000000E+00 +E_domain_decomp_c6_dc10_e2 289 290 217 1 -0.000000E+00 +E_domain_decomp_c6_dc11_e2 290 291 218 1 1.000000E+00 +E_domain_decomp_c6_dc12_e2 291 1 219 1 -0.000000E+00 +E_domain_decomp_c7_dc1_e2 292 293 208 1 0.000000E+00 +E_domain_decomp_c7_dc2_e2 293 294 209 1 0.000000E+00 +E_domain_decomp_c7_dc3_e2 294 295 210 1 0.000000E+00 +E_domain_decomp_c7_dc4_e2 295 296 211 1 0.000000E+00 +E_domain_decomp_c7_dc5_e2 296 297 212 1 0.000000E+00 +E_domain_decomp_c7_dc6_e2 297 298 213 1 0.000000E+00 +E_domain_decomp_c7_dc7_e2 298 299 214 1 5.000000E-01 +E_domain_decomp_c7_dc8_e2 299 300 215 1 1.000000E+00 +E_domain_decomp_c7_dc9_e2 300 301 216 1 0.000000E+00 +E_domain_decomp_c7_dc10_e2 301 302 217 1 0.000000E+00 +E_domain_decomp_c7_dc11_e2 302 303 218 1 -0.000000E+00 +E_domain_decomp_c7_dc12_e2 303 1 219 1 1.000000E+00 +E_domain_decomp_c8_dc1_e2 304 305 208 1 0.000000E+00 +E_domain_decomp_c8_dc2_e2 305 306 209 1 0.000000E+00 +E_domain_decomp_c8_dc3_e2 306 307 210 1 0.000000E+00 +E_domain_decomp_c8_dc4_e2 307 308 211 1 0.000000E+00 +E_domain_decomp_c8_dc5_e2 308 309 212 1 0.000000E+00 +E_domain_decomp_c8_dc6_e2 309 310 213 1 0.000000E+00 +E_domain_decomp_c8_dc7_e2 310 311 214 1 -5.000000E-01 +E_domain_decomp_c8_dc8_e2 311 312 215 1 1.000000E+00 +E_domain_decomp_c8_dc9_e2 312 313 216 1 0.000000E+00 +E_domain_decomp_c8_dc10_e2 313 314 217 1 0.000000E+00 +E_domain_decomp_c8_dc11_e2 314 315 218 1 -0.000000E+00 +E_domain_decomp_c8_dc12_e2 315 1 219 1 1.000000E+00 +E_domain_decomp_c9_dc1_e2 316 317 208 1 0.000000E+00 +E_domain_decomp_c9_dc2_e2 317 318 209 1 0.000000E+00 +E_domain_decomp_c9_dc3_e2 318 319 210 1 0.000000E+00 +E_domain_decomp_c9_dc4_e2 319 320 211 1 0.000000E+00 +E_domain_decomp_c9_dc5_e2 320 321 212 1 0.000000E+00 +E_domain_decomp_c9_dc6_e2 321 322 213 1 0.000000E+00 +E_domain_decomp_c9_dc7_e2 322 323 214 1 0.000000E+00 +E_domain_decomp_c9_dc8_e2 323 324 215 1 -0.000000E+00 +E_domain_decomp_c9_dc9_e2 324 325 216 1 1.000000E+00 +E_domain_decomp_c9_dc10_e2 325 326 217 1 0.000000E+00 +E_domain_decomp_c9_dc11_e2 326 327 218 1 0.000000E+00 +E_domain_decomp_c9_dc12_e2 327 1 219 1 -0.000000E+00 +E_domain_decomp_c10_dc1_e2 328 329 208 1 0.000000E+00 +E_domain_decomp_c10_dc2_e2 329 330 209 1 0.000000E+00 +E_domain_decomp_c10_dc3_e2 330 331 210 1 0.000000E+00 +E_domain_decomp_c10_dc4_e2 331 332 211 1 0.000000E+00 +E_domain_decomp_c10_dc5_e2 332 333 212 1 0.000000E+00 +E_domain_decomp_c10_dc6_e2 333 334 213 1 0.000000E+00 +E_domain_decomp_c10_dc7_e2 334 335 214 1 0.000000E+00 +E_domain_decomp_c10_dc8_e2 335 336 215 1 0.000000E+00 +E_domain_decomp_c10_dc9_e2 336 337 216 1 -0.000000E+00 +E_domain_decomp_c10_dc10_e2 337 338 217 1 1.000000E+00 +E_domain_decomp_c10_dc11_e2 338 339 218 1 0.000000E+00 +E_domain_decomp_c10_dc12_e2 339 1 219 1 -0.000000E+00 +E_domain_decomp_c11_dc1_e2 340 341 208 1 0.000000E+00 +E_domain_decomp_c11_dc2_e2 341 342 209 1 0.000000E+00 +E_domain_decomp_c11_dc3_e2 342 343 210 1 0.000000E+00 +E_domain_decomp_c11_dc4_e2 343 344 211 1 0.000000E+00 +E_domain_decomp_c11_dc5_e2 344 345 212 1 0.000000E+00 +E_domain_decomp_c11_dc6_e2 345 346 213 1 0.000000E+00 +E_domain_decomp_c11_dc7_e2 346 347 214 1 0.000000E+00 +E_domain_decomp_c11_dc8_e2 347 348 215 1 0.000000E+00 +E_domain_decomp_c11_dc9_e2 348 349 216 1 0.000000E+00 +E_domain_decomp_c11_dc10_e2 349 350 217 1 -0.000000E+00 +E_domain_decomp_c11_dc11_e2 350 351 218 1 1.000000E+00 +E_domain_decomp_c11_dc12_e2 351 1 219 1 -0.000000E+00 +E_domain_decomp_c12_dc1_e2 352 353 208 1 0.000000E+00 +E_domain_decomp_c12_dc2_e2 353 354 209 1 0.000000E+00 +E_domain_decomp_c12_dc3_e2 354 355 210 1 0.000000E+00 +E_domain_decomp_c12_dc4_e2 355 356 211 1 0.000000E+00 +E_domain_decomp_c12_dc5_e2 356 357 212 1 0.000000E+00 +E_domain_decomp_c12_dc6_e2 357 358 213 1 0.000000E+00 +E_domain_decomp_c12_dc7_e2 358 359 214 1 0.000000E+00 +E_domain_decomp_c12_dc8_e2 359 360 215 1 0.000000E+00 +E_domain_decomp_c12_dc9_e2 360 361 216 1 0.000000E+00 +E_domain_decomp_c12_dc10_e2 361 362 217 1 0.000000E+00 +E_domain_decomp_c12_dc11_e2 362 363 218 1 -0.000000E+00 +E_domain_decomp_c12_dc12_e2 363 1 219 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 208 Vmeas_domain_decomp_c1_e2 5.000000E-01 +F_domain_decomp_c2_dc1_e2 1 208 Vmeas_domain_decomp_c2_e2 -5.000000E-01 +F_domain_decomp_c3_dc1_e2 1 208 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc1_e2 1 208 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc1_e2 1 208 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc1_e2 1 208 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc1_e2 1 208 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc1_e2 1 208 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc1_e2 1 208 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc1_e2 1 208 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc1_e2 1 208 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc1_e2 1 208 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 209 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc2_e2 1 209 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c3_dc2_e2 1 209 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc2_e2 1 209 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc2_e2 1 209 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc2_e2 1 209 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc2_e2 1 209 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc2_e2 1 209 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc2_e2 1 209 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc2_e2 1 209 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc2_e2 1 209 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc2_e2 1 209 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc3_e2 1 210 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc3_e2 1 210 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc3_e2 1 210 Vmeas_domain_decomp_c3_e2 5.000000E-01 +F_domain_decomp_c4_dc3_e2 1 210 Vmeas_domain_decomp_c4_e2 -5.000000E-01 +F_domain_decomp_c5_dc3_e2 1 210 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc3_e2 1 210 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc3_e2 1 210 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc3_e2 1 210 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc3_e2 1 210 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc3_e2 1 210 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc3_e2 1 210 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc3_e2 1 210 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc4_e2 1 211 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc4_e2 1 211 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc4_e2 1 211 Vmeas_domain_decomp_c3_e2 1.000000E+00 +F_domain_decomp_c4_dc4_e2 1 211 Vmeas_domain_decomp_c4_e2 1.000000E+00 +F_domain_decomp_c5_dc4_e2 1 211 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc4_e2 1 211 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc4_e2 1 211 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc4_e2 1 211 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc4_e2 1 211 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc4_e2 1 211 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc4_e2 1 211 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc4_e2 1 211 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc5_e2 1 212 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc5_e2 1 212 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc5_e2 1 212 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc5_e2 1 212 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc5_e2 1 212 Vmeas_domain_decomp_c5_e2 5.000000E-01 +F_domain_decomp_c6_dc5_e2 1 212 Vmeas_domain_decomp_c6_e2 -5.000000E-01 +F_domain_decomp_c7_dc5_e2 1 212 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc5_e2 1 212 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc5_e2 1 212 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc5_e2 1 212 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc5_e2 1 212 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc5_e2 1 212 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc6_e2 1 213 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc6_e2 1 213 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc6_e2 1 213 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc6_e2 1 213 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc6_e2 1 213 Vmeas_domain_decomp_c5_e2 1.000000E+00 +F_domain_decomp_c6_dc6_e2 1 213 Vmeas_domain_decomp_c6_e2 1.000000E+00 +F_domain_decomp_c7_dc6_e2 1 213 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc6_e2 1 213 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc6_e2 1 213 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc6_e2 1 213 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc6_e2 1 213 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc6_e2 1 213 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc7_e2 1 214 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc7_e2 1 214 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc7_e2 1 214 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc7_e2 1 214 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc7_e2 1 214 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc7_e2 1 214 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc7_e2 1 214 Vmeas_domain_decomp_c7_e2 5.000000E-01 +F_domain_decomp_c8_dc7_e2 1 214 Vmeas_domain_decomp_c8_e2 -5.000000E-01 +F_domain_decomp_c9_dc7_e2 1 214 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc7_e2 1 214 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc7_e2 1 214 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc7_e2 1 214 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc8_e2 1 215 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc8_e2 1 215 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc8_e2 1 215 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc8_e2 1 215 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc8_e2 1 215 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc8_e2 1 215 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc8_e2 1 215 Vmeas_domain_decomp_c7_e2 1.000000E+00 +F_domain_decomp_c8_dc8_e2 1 215 Vmeas_domain_decomp_c8_e2 1.000000E+00 +F_domain_decomp_c9_dc8_e2 1 215 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc8_e2 1 215 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc8_e2 1 215 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc8_e2 1 215 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc9_e2 1 216 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc9_e2 1 216 Vmeas_domain_decomp_c2_e2 1.000000E+00 +F_domain_decomp_c3_dc9_e2 1 216 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc9_e2 1 216 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc9_e2 1 216 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc9_e2 1 216 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc9_e2 1 216 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc9_e2 1 216 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc9_e2 1 216 Vmeas_domain_decomp_c9_e2 1.000000E+00 +F_domain_decomp_c10_dc9_e2 1 216 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc9_e2 1 216 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc9_e2 1 216 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc10_e2 1 217 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc10_e2 1 217 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc10_e2 1 217 Vmeas_domain_decomp_c3_e2 1.000000E+00 +F_domain_decomp_c4_dc10_e2 1 217 Vmeas_domain_decomp_c4_e2 1.000000E+00 +F_domain_decomp_c5_dc10_e2 1 217 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc10_e2 1 217 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc10_e2 1 217 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc10_e2 1 217 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc10_e2 1 217 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc10_e2 1 217 Vmeas_domain_decomp_c10_e2 1.000000E+00 +F_domain_decomp_c11_dc10_e2 1 217 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc10_e2 1 217 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc11_e2 1 218 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc11_e2 1 218 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc11_e2 1 218 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc11_e2 1 218 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc11_e2 1 218 Vmeas_domain_decomp_c5_e2 1.000000E+00 +F_domain_decomp_c6_dc11_e2 1 218 Vmeas_domain_decomp_c6_e2 1.000000E+00 +F_domain_decomp_c7_dc11_e2 1 218 Vmeas_domain_decomp_c7_e2 0.000000E+00 +F_domain_decomp_c8_dc11_e2 1 218 Vmeas_domain_decomp_c8_e2 0.000000E+00 +F_domain_decomp_c9_dc11_e2 1 218 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc11_e2 1 218 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc11_e2 1 218 Vmeas_domain_decomp_c11_e2 1.000000E+00 +F_domain_decomp_c12_dc11_e2 1 218 Vmeas_domain_decomp_c12_e2 0.000000E+00 +F_domain_decomp_c1_dc12_e2 1 219 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc12_e2 1 219 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c3_dc12_e2 1 219 Vmeas_domain_decomp_c3_e2 0.000000E+00 +F_domain_decomp_c4_dc12_e2 1 219 Vmeas_domain_decomp_c4_e2 0.000000E+00 +F_domain_decomp_c5_dc12_e2 1 219 Vmeas_domain_decomp_c5_e2 0.000000E+00 +F_domain_decomp_c6_dc12_e2 1 219 Vmeas_domain_decomp_c6_e2 0.000000E+00 +F_domain_decomp_c7_dc12_e2 1 219 Vmeas_domain_decomp_c7_e2 1.000000E+00 +F_domain_decomp_c8_dc12_e2 1 219 Vmeas_domain_decomp_c8_e2 1.000000E+00 +F_domain_decomp_c9_dc12_e2 1 219 Vmeas_domain_decomp_c9_e2 0.000000E+00 +F_domain_decomp_c10_dc12_e2 1 219 Vmeas_domain_decomp_c10_e2 0.000000E+00 +F_domain_decomp_c11_dc12_e2 1 219 Vmeas_domain_decomp_c11_e2 0.000000E+00 +F_domain_decomp_c12_dc12_e2 1 219 Vmeas_domain_decomp_c12_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 52 365 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 365 1 364 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 364 Vmeas_mode_decomp_d1_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 208 367 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 367 1 366 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 366 Vmeas_mode_decomp_d1_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 364 368 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 366 369 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 368 1 370 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 369 1 371 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m1_e1 371 1 372 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Delay line for negative z propagation +* +T_mz_d1_m1_e2 370 1 373 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 371 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 370 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 372 374 364 1 2.000000E+00 +E_m_pz_d1_m1_e2 374 1 368 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 373 375 366 1 2.000000E+00 +E_m_mz_d1_m1_e2 375 1 369 1 -1.000000E+00 +* +* DOMAIN 2 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e1 53 377 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e1 377 1 376 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e1 1 376 Vmeas_mode_decomp_d2_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d2_c1_e2 209 379 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d2_c1_m1_e2 379 1 378 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d2_c1_m1_e2 1 378 Vmeas_mode_decomp_d2_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d2_m1_e1 376 380 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d2_m1_e2 378 381 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d2_m1_e1 380 1 382 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d2_m1_e2 381 1 383 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d2_m1_e1 383 1 384 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Delay line for negative z propagation +* +T_mz_d2_m1_e2 382 1 385 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d2_m1_e1 383 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d2_m1_e2 382 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d2_m1_e1 384 386 376 1 2.000000E+00 +E_m_pz_d2_m1_e2 386 1 380 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d2_m1_e1 385 387 378 1 2.000000E+00 +E_m_mz_d2_m1_e2 387 1 381 1 -1.000000E+00 +* +* DOMAIN 3 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d3_c1_e1 54 389 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d3_c1_m1_e1 389 1 388 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d3_c1_m1_e1 1 388 Vmeas_mode_decomp_d3_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d3_c1_e2 210 391 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d3_c1_m1_e2 391 1 390 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d3_c1_m1_e2 1 390 Vmeas_mode_decomp_d3_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d3_m1_e1 388 392 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d3_m1_e2 390 393 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d3_m1_e1 392 1 394 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d3_m1_e2 393 1 395 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d3_m1_e1 395 1 396 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Delay line for negative z propagation +* +T_mz_d3_m1_e2 394 1 397 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d3_m1_e1 395 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d3_m1_e2 394 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d3_m1_e1 396 398 388 1 2.000000E+00 +E_m_pz_d3_m1_e2 398 1 392 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d3_m1_e1 397 399 390 1 2.000000E+00 +E_m_mz_d3_m1_e2 399 1 393 1 -1.000000E+00 +* +* DOMAIN 4 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d4_c1_e1 55 401 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d4_c1_m1_e1 401 1 400 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d4_c1_m1_e1 1 400 Vmeas_mode_decomp_d4_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d4_c1_e2 211 403 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d4_c1_m1_e2 403 1 402 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d4_c1_m1_e2 1 402 Vmeas_mode_decomp_d4_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d4_m1_e1 400 404 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d4_m1_e2 402 405 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d4_m1_e1 404 1 406 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d4_m1_e2 405 1 407 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d4_m1_e1 407 1 408 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Delay line for negative z propagation +* +T_mz_d4_m1_e2 406 1 409 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d4_m1_e1 407 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d4_m1_e2 406 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d4_m1_e1 408 410 400 1 2.000000E+00 +E_m_pz_d4_m1_e2 410 1 404 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d4_m1_e1 409 411 402 1 2.000000E+00 +E_m_mz_d4_m1_e2 411 1 405 1 -1.000000E+00 +* +* DOMAIN 5 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d5_c1_e1 56 413 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d5_c1_m1_e1 413 1 412 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d5_c1_m1_e1 1 412 Vmeas_mode_decomp_d5_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d5_c1_e2 212 415 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d5_c1_m1_e2 415 1 414 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d5_c1_m1_e2 1 414 Vmeas_mode_decomp_d5_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d5_m1_e1 412 416 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d5_m1_e2 414 417 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d5_m1_e1 416 1 418 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d5_m1_e2 417 1 419 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d5_m1_e1 419 1 420 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Delay line for negative z propagation +* +T_mz_d5_m1_e2 418 1 421 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d5_m1_e1 419 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d5_m1_e2 418 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d5_m1_e1 420 422 412 1 2.000000E+00 +E_m_pz_d5_m1_e2 422 1 416 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d5_m1_e1 421 423 414 1 2.000000E+00 +E_m_mz_d5_m1_e2 423 1 417 1 -1.000000E+00 +* +* DOMAIN 6 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d6_c1_e1 57 425 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d6_c1_m1_e1 425 1 424 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d6_c1_m1_e1 1 424 Vmeas_mode_decomp_d6_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d6_c1_e2 213 427 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d6_c1_m1_e2 427 1 426 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d6_c1_m1_e2 1 426 Vmeas_mode_decomp_d6_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d6_m1_e1 424 428 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d6_m1_e2 426 429 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d6_m1_e1 428 1 430 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d6_m1_e2 429 1 431 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d6_m1_e1 431 1 432 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Delay line for negative z propagation +* +T_mz_d6_m1_e2 430 1 433 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d6_m1_e1 431 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d6_m1_e2 430 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d6_m1_e1 432 434 424 1 2.000000E+00 +E_m_pz_d6_m1_e2 434 1 428 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d6_m1_e1 433 435 426 1 2.000000E+00 +E_m_mz_d6_m1_e2 435 1 429 1 -1.000000E+00 +* +* DOMAIN 7 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d7_c1_e1 58 437 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d7_c1_m1_e1 437 1 436 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d7_c1_m1_e1 1 436 Vmeas_mode_decomp_d7_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d7_c1_e2 214 439 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d7_c1_m1_e2 439 1 438 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d7_c1_m1_e2 1 438 Vmeas_mode_decomp_d7_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d7_m1_e1 436 440 1.194535E+02 +* +* Modal impedance: end2 +* +RZCm_d7_m1_e2 438 441 1.194535E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d7_m1_e1 440 1 442 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d7_m1_e2 441 1 443 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d7_m1_e1 443 1 444 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Delay line for negative z propagation +* +T_mz_d7_m1_e2 442 1 445 1 LEN= 1.000000E+00 ++ R=0.0 L= 4.825545E-07 G=0.0 C= 3.381805E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d7_m1_e1 443 1 1.194535E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d7_m1_e2 442 1 1.194535E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d7_m1_e1 444 446 436 1 2.000000E+00 +E_m_pz_d7_m1_e2 446 1 440 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d7_m1_e1 445 447 438 1 2.000000E+00 +E_m_mz_d7_m1_e2 447 1 441 1 -1.000000E+00 +* +* DOMAIN 8 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d8_c1_e1 59 449 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d8_c1_m1_e1 449 1 448 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d8_c1_m1_e1 1 448 Vmeas_mode_decomp_d8_c1_e1 1.00000000E+00 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d8_c1_e2 215 451 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d8_c1_m1_e2 451 1 450 1 1.00000000E+00 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d8_c1_m1_e2 1 450 Vmeas_mode_decomp_d8_c1_e2 1.00000000E+00 +* +* Modal impedance: end1 +* +RZCm_d8_m1_e1 448 452 7.464194E+01 +* +* Modal impedance: end2 +* +RZCm_d8_m1_e2 450 453 7.464194E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d8_m1_e1 452 1 454 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d8_m1_e2 453 1 455 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d8_m1_e1 455 1 456 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Delay line for negative z propagation +* +T_mz_d8_m1_e2 454 1 457 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.686772E-07 G=0.0 C= 4.822420E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d8_m1_e1 455 1 7.464194E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d8_m1_e2 454 1 7.464194E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d8_m1_e1 456 458 448 1 2.000000E+00 +E_m_pz_d8_m1_e2 458 1 452 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d8_m1_e1 457 459 450 1 2.000000E+00 +E_m_mz_d8_m1_e2 459 1 453 1 -1.000000E+00 +* +* DOMAIN 9 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d9_c1_e1 60 464 +Vmeas_mode_decomp_d9_c2_e1 61 468 +Vmeas_mode_decomp_d9_c3_e1 62 472 +Vmeas_mode_decomp_d9_c4_e1 63 476 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d9_c1_m1_e1 464 465 460 1 4.99997010E-01 +E_mode_decomp_d9_c1_m2_e1 465 466 461 1 6.60299603E-01 +E_mode_decomp_d9_c1_m3_e1 466 467 462 1 -2.52110920E-01 +E_mode_decomp_d9_c1_m4_e1 467 1 463 1 5.00566867E-01 +E_mode_decomp_d9_c2_m1_e1 468 469 460 1 5.00000814E-01 +E_mode_decomp_d9_c2_m2_e1 469 470 461 1 2.52638434E-01 +E_mode_decomp_d9_c2_m3_e1 470 471 462 1 6.60216363E-01 +E_mode_decomp_d9_c2_m4_e1 471 1 463 1 -5.00372583E-01 +E_mode_decomp_d9_c3_m1_e1 472 473 460 1 5.00001652E-01 +E_mode_decomp_d9_c3_m2_e1 473 474 461 1 -6.60745021E-01 +E_mode_decomp_d9_c3_m3_e1 474 475 462 1 2.52713880E-01 +E_mode_decomp_d9_c3_m4_e1 475 1 463 1 4.99437438E-01 +E_mode_decomp_d9_c4_m1_e1 476 477 460 1 5.00000524E-01 +E_mode_decomp_d9_c4_m2_e1 477 478 461 1 -2.52179072E-01 +E_mode_decomp_d9_c4_m3_e1 478 479 462 1 -6.60825366E-01 +E_mode_decomp_d9_c4_m4_e1 479 1 463 1 -4.99622234E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d9_c1_m1_e1 1 460 Vmeas_mode_decomp_d9_c1_e1 4.99997010E-01 +F_mode_decomp_d9_c2_m1_e1 1 460 Vmeas_mode_decomp_d9_c2_e1 5.00000814E-01 +F_mode_decomp_d9_c3_m1_e1 1 460 Vmeas_mode_decomp_d9_c3_e1 5.00001652E-01 +F_mode_decomp_d9_c4_m1_e1 1 460 Vmeas_mode_decomp_d9_c4_e1 5.00000524E-01 +F_mode_decomp_d9_c1_m2_e1 1 461 Vmeas_mode_decomp_d9_c1_e1 6.60299603E-01 +F_mode_decomp_d9_c2_m2_e1 1 461 Vmeas_mode_decomp_d9_c2_e1 2.52638434E-01 +F_mode_decomp_d9_c3_m2_e1 1 461 Vmeas_mode_decomp_d9_c3_e1 -6.60745021E-01 +F_mode_decomp_d9_c4_m2_e1 1 461 Vmeas_mode_decomp_d9_c4_e1 -2.52179072E-01 +F_mode_decomp_d9_c1_m3_e1 1 462 Vmeas_mode_decomp_d9_c1_e1 -2.52110920E-01 +F_mode_decomp_d9_c2_m3_e1 1 462 Vmeas_mode_decomp_d9_c2_e1 6.60216363E-01 +F_mode_decomp_d9_c3_m3_e1 1 462 Vmeas_mode_decomp_d9_c3_e1 2.52713880E-01 +F_mode_decomp_d9_c4_m3_e1 1 462 Vmeas_mode_decomp_d9_c4_e1 -6.60825366E-01 +F_mode_decomp_d9_c1_m4_e1 1 463 Vmeas_mode_decomp_d9_c1_e1 5.00566867E-01 +F_mode_decomp_d9_c2_m4_e1 1 463 Vmeas_mode_decomp_d9_c2_e1 -5.00372583E-01 +F_mode_decomp_d9_c3_m4_e1 1 463 Vmeas_mode_decomp_d9_c3_e1 4.99437438E-01 +F_mode_decomp_d9_c4_m4_e1 1 463 Vmeas_mode_decomp_d9_c4_e1 -4.99622234E-01 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d9_c1_e2 216 484 +Vmeas_mode_decomp_d9_c2_e2 217 488 +Vmeas_mode_decomp_d9_c3_e2 218 492 +Vmeas_mode_decomp_d9_c4_e2 219 496 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d9_c1_m1_e2 484 485 480 1 4.99997010E-01 +E_mode_decomp_d9_c1_m2_e2 485 486 481 1 6.60299603E-01 +E_mode_decomp_d9_c1_m3_e2 486 487 482 1 -2.52110920E-01 +E_mode_decomp_d9_c1_m4_e2 487 1 483 1 5.00566867E-01 +E_mode_decomp_d9_c2_m1_e2 488 489 480 1 5.00000814E-01 +E_mode_decomp_d9_c2_m2_e2 489 490 481 1 2.52638434E-01 +E_mode_decomp_d9_c2_m3_e2 490 491 482 1 6.60216363E-01 +E_mode_decomp_d9_c2_m4_e2 491 1 483 1 -5.00372583E-01 +E_mode_decomp_d9_c3_m1_e2 492 493 480 1 5.00001652E-01 +E_mode_decomp_d9_c3_m2_e2 493 494 481 1 -6.60745021E-01 +E_mode_decomp_d9_c3_m3_e2 494 495 482 1 2.52713880E-01 +E_mode_decomp_d9_c3_m4_e2 495 1 483 1 4.99437438E-01 +E_mode_decomp_d9_c4_m1_e2 496 497 480 1 5.00000524E-01 +E_mode_decomp_d9_c4_m2_e2 497 498 481 1 -2.52179072E-01 +E_mode_decomp_d9_c4_m3_e2 498 499 482 1 -6.60825366E-01 +E_mode_decomp_d9_c4_m4_e2 499 1 483 1 -4.99622234E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d9_c1_m1_e2 1 480 Vmeas_mode_decomp_d9_c1_e2 4.99997010E-01 +F_mode_decomp_d9_c2_m1_e2 1 480 Vmeas_mode_decomp_d9_c2_e2 5.00000814E-01 +F_mode_decomp_d9_c3_m1_e2 1 480 Vmeas_mode_decomp_d9_c3_e2 5.00001652E-01 +F_mode_decomp_d9_c4_m1_e2 1 480 Vmeas_mode_decomp_d9_c4_e2 5.00000524E-01 +F_mode_decomp_d9_c1_m2_e2 1 481 Vmeas_mode_decomp_d9_c1_e2 6.60299603E-01 +F_mode_decomp_d9_c2_m2_e2 1 481 Vmeas_mode_decomp_d9_c2_e2 2.52638434E-01 +F_mode_decomp_d9_c3_m2_e2 1 481 Vmeas_mode_decomp_d9_c3_e2 -6.60745021E-01 +F_mode_decomp_d9_c4_m2_e2 1 481 Vmeas_mode_decomp_d9_c4_e2 -2.52179072E-01 +F_mode_decomp_d9_c1_m3_e2 1 482 Vmeas_mode_decomp_d9_c1_e2 -2.52110920E-01 +F_mode_decomp_d9_c2_m3_e2 1 482 Vmeas_mode_decomp_d9_c2_e2 6.60216363E-01 +F_mode_decomp_d9_c3_m3_e2 1 482 Vmeas_mode_decomp_d9_c3_e2 2.52713880E-01 +F_mode_decomp_d9_c4_m3_e2 1 482 Vmeas_mode_decomp_d9_c4_e2 -6.60825366E-01 +F_mode_decomp_d9_c1_m4_e2 1 483 Vmeas_mode_decomp_d9_c1_e2 5.00566867E-01 +F_mode_decomp_d9_c2_m4_e2 1 483 Vmeas_mode_decomp_d9_c2_e2 -5.00372583E-01 +F_mode_decomp_d9_c3_m4_e2 1 483 Vmeas_mode_decomp_d9_c3_e2 4.99437438E-01 +F_mode_decomp_d9_c4_m4_e2 1 483 Vmeas_mode_decomp_d9_c4_e2 -4.99622234E-01 +* +* Modal impedance: end1 +* +RZCm_d9_m1_e1 460 500 9.322448E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m1_e2 480 501 9.322448E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m1_e1 500 1 502 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m1_e2 501 1 503 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d9_m1_e1 503 1 504 1 LEN= 1.000000E+00 ++ R=0.0 L= 3.236033E-07 G=0.0 C= 3.723514E-11 +* +* Delay line for negative z propagation +* +T_mz_d9_m1_e2 502 1 505 1 LEN= 1.000000E+00 ++ R=0.0 L= 3.236033E-07 G=0.0 C= 3.723514E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m1_e1 503 1 9.322448E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m1_e2 502 1 9.322448E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m1_e1 504 506 460 1 2.000000E+00 +E_m_pz_d9_m1_e2 506 1 500 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m1_e1 505 507 480 1 2.000000E+00 +E_m_mz_d9_m1_e2 507 1 501 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m2_e1 461 508 4.294265E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m2_e2 481 509 4.294265E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m2_e1 508 1 510 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m2_e2 509 1 511 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d9_m2_e1 511 1 512 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.530171E-07 G=0.0 C= 8.297789E-11 +* +* Delay line for negative z propagation +* +T_mz_d9_m2_e2 510 1 513 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.530171E-07 G=0.0 C= 8.297789E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m2_e1 511 1 4.294265E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m2_e2 510 1 4.294265E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m2_e1 512 514 461 1 2.000000E+00 +E_m_pz_d9_m2_e2 514 1 508 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m2_e1 513 515 481 1 2.000000E+00 +E_m_mz_d9_m2_e2 515 1 509 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m3_e1 462 516 4.294177E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m3_e2 482 517 4.294177E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m3_e1 516 1 518 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m3_e2 517 1 519 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d9_m3_e1 519 1 520 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.530143E-07 G=0.0 C= 8.297977E-11 +* +* Delay line for negative z propagation +* +T_mz_d9_m3_e2 518 1 521 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.530143E-07 G=0.0 C= 8.297977E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m3_e1 519 1 4.294177E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m3_e2 518 1 4.294177E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m3_e1 520 522 462 1 2.000000E+00 +E_m_pz_d9_m3_e2 522 1 516 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m3_e1 521 523 482 1 2.000000E+00 +E_m_mz_d9_m3_e2 523 1 517 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d9_m4_e1 463 524 2.983334E+01 +* +* Modal impedance: end2 +* +RZCm_d9_m4_e2 483 525 2.983334E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d9_m4_e1 524 1 526 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d9_m4_e2 525 1 527 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d9_m4_e1 527 1 528 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.076602E-07 G=0.0 C= 1.209627E-10 +* +* Delay line for negative z propagation +* +T_mz_d9_m4_e2 526 1 529 1 LEN= 1.000000E+00 ++ R=0.0 L= 1.076602E-07 G=0.0 C= 1.209627E-10 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d9_m4_e1 527 1 2.983334E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d9_m4_e2 526 1 2.983334E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d9_m4_e1 528 530 463 1 2.000000E+00 +E_m_pz_d9_m4_e2 530 1 524 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d9_m4_e1 529 531 483 1 2.000000E+00 +E_m_mz_d9_m4_e2 531 1 525 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax.spice_model_spec b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax.spice_model_spec new file mode 100644 index 0000000..8a97f4a --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax.spice_model_spec @@ -0,0 +1,19 @@ +# MOD_cable_lib_dir +../MOD_WEB_EXAMPLES/CABLE/ +# MOD_bundle_lib_dir +../MOD_WEB_EXAMPLES/BUNDLE/ +# MOD_spice_bundle_lib_dir +../MOD_WEB_EXAMPLES/SPICE/ +# spice_symbol_dir +../MOD_WEB_EXAMPLES/SPICE/SYMBOL/ +# Specification for spice model of ZT_FD_Twinax +ZT_FD_twinax +# cable bundle length (m) +1.0 +# Incident field specification +0 amplitude (V/m) +0 0 ktheta kphi (degrees) +0 0 Etheta Ephi (degrees) +# Transfer Impedance Model +0 # number of transfer impedances to include in the model +No_validation_test \ No newline at end of file diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_LTspice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_LTspice.lib new file mode 100644 index 0000000..11516f5 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_LTspice.lib @@ -0,0 +1,216 @@ +* LTspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 +* node: 3 Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 +* node: 4 Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 +* node: 6 Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 +* node: 7 Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield +* +.subckt ZT_FD_Twinax ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.092958E-02 +Rdc_c2_e1 3 9 5.092958E-02 +Rdc_c3_e1 4 1 5.000000E-02 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.092958E-02 +Rdc_c2_e2 6 11 5.092958E-02 +Rdc_c3_e2 7 1 5.000000E-02 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 1.000000E+00 +E_domain_decomp_c1_dc2_e1 15 1 13 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 1.000000E+00 +E_domain_decomp_c1_dc2_e2 21 1 19 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 26 +Vmeas_mode_decomp_d1_c2_e1 13 28 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 26 27 24 1 -7.07106781E-01 +E_mode_decomp_d1_c1_m2_e1 27 1 25 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m1_e1 28 29 24 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m2_e1 29 1 25 1 7.07106781E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 -7.07106781E-01 +F_mode_decomp_d1_c2_m1_e1 1 24 Vmeas_mode_decomp_d1_c2_e1 -7.07106781E-01 +F_mode_decomp_d1_c1_m2_e1 1 25 Vmeas_mode_decomp_d1_c1_e1 -7.07106781E-01 +F_mode_decomp_d1_c2_m2_e1 1 25 Vmeas_mode_decomp_d1_c2_e1 7.07106781E-01 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 32 +Vmeas_mode_decomp_d1_c2_e2 19 34 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 32 33 30 1 -7.07106781E-01 +E_mode_decomp_d1_c1_m2_e2 33 1 31 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m1_e2 34 35 30 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m2_e2 35 1 31 1 7.07106781E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 30 Vmeas_mode_decomp_d1_c1_e2 -7.07106781E-01 +F_mode_decomp_d1_c2_m1_e2 1 30 Vmeas_mode_decomp_d1_c2_e2 -7.07106781E-01 +F_mode_decomp_d1_c1_m2_e2 1 31 Vmeas_mode_decomp_d1_c1_e2 -7.07106781E-01 +F_mode_decomp_d1_c2_m2_e2 1 31 Vmeas_mode_decomp_d1_c2_e2 7.07106781E-01 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 36 1.106704E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 30 37 1.106704E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 36 1 38 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 37 1 39 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 39 1 40 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 5.537350E-07 C= 4.521048E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 38 1 41 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 5.537350E-07 C= 4.521048E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 39 1 1.106704E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 38 1 1.106704E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 40 42 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 42 1 36 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 41 43 30 1 2.000000E+00 +E_m_mz_d1_m1_e2 43 1 37 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m2_e1 25 44 5.041035E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m2_e2 31 45 5.041035E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m2_e1 44 1 46 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m2_e2 45 1 47 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m2_e1 47 1 48 1 LTRA_T_pz_d1_m2_e1 +.MODEL LTRA_T_pz_d1_m2_e1 LTRA( R=0.0 L= 2.522262E-07 C= 9.925464E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m2_e2 46 1 49 1 LTRA_T_mz_d1_m2_e2 +.MODEL LTRA_T_mz_d1_m2_e2 LTRA( R=0.0 L= 2.522262E-07 C= 9.925464E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m2_e1 47 1 5.041035E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m2_e2 46 1 5.041035E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m2_e1 48 50 25 1 2.000000E+00 +E_m_pz_d1_m2_e2 50 1 44 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m2_e1 49 51 31 1 2.000000E+00 +E_m_mz_d1_m2_e2 51 1 45 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_Ngspice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_Ngspice.lib new file mode 100644 index 0000000..409af17 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_Ngspice.lib @@ -0,0 +1,216 @@ +* Ngspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 +* node: 3 Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 +* node: 4 Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 +* node: 6 Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 +* node: 7 Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield +* +.subckt ZT_FD_Twinax ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.092958E-02 +Rdc_c2_e1 3 9 5.092958E-02 +Rdc_c3_e1 4 1 5.000000E-02 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.092958E-02 +Rdc_c2_e2 6 11 5.092958E-02 +Rdc_c3_e2 7 1 5.000000E-02 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 1.000000E+00 +E_domain_decomp_c1_dc2_e1 15 1 13 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 1.000000E+00 +E_domain_decomp_c1_dc2_e2 21 1 19 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 26 +Vmeas_mode_decomp_d1_c2_e1 13 28 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 26 27 24 1 -7.07106781E-01 +E_mode_decomp_d1_c1_m2_e1 27 1 25 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m1_e1 28 29 24 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m2_e1 29 1 25 1 7.07106781E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 -7.07106781E-01 +F_mode_decomp_d1_c2_m1_e1 1 24 Vmeas_mode_decomp_d1_c2_e1 -7.07106781E-01 +F_mode_decomp_d1_c1_m2_e1 1 25 Vmeas_mode_decomp_d1_c1_e1 -7.07106781E-01 +F_mode_decomp_d1_c2_m2_e1 1 25 Vmeas_mode_decomp_d1_c2_e1 7.07106781E-01 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 32 +Vmeas_mode_decomp_d1_c2_e2 19 34 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 32 33 30 1 -7.07106781E-01 +E_mode_decomp_d1_c1_m2_e2 33 1 31 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m1_e2 34 35 30 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m2_e2 35 1 31 1 7.07106781E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 30 Vmeas_mode_decomp_d1_c1_e2 -7.07106781E-01 +F_mode_decomp_d1_c2_m1_e2 1 30 Vmeas_mode_decomp_d1_c2_e2 -7.07106781E-01 +F_mode_decomp_d1_c1_m2_e2 1 31 Vmeas_mode_decomp_d1_c1_e2 -7.07106781E-01 +F_mode_decomp_d1_c2_m2_e2 1 31 Vmeas_mode_decomp_d1_c2_e2 7.07106781E-01 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 36 1.106704E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 30 37 1.106704E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 36 1 38 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 37 1 39 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m1_e1 39 1 40 1 LTRA_T_pz_d1_m1_e1 +.MODEL LTRA_T_pz_d1_m1_e1 LTRA( R=0.0 L= 5.537350E-07 C= 4.521048E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m1_e2 38 1 41 1 LTRA_T_mz_d1_m1_e2 +.MODEL LTRA_T_mz_d1_m1_e2 LTRA( R=0.0 L= 5.537350E-07 C= 4.521048E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 39 1 1.106704E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 38 1 1.106704E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 40 42 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 42 1 36 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 41 43 30 1 2.000000E+00 +E_m_mz_d1_m1_e2 43 1 37 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m2_e1 25 44 5.041035E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m2_e2 31 45 5.041035E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m2_e1 44 1 46 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m2_e2 45 1 47 1 1.000000E+00 +* +* Delay line for positive z propagation +* +O_T_pz_d1_m2_e1 47 1 48 1 LTRA_T_pz_d1_m2_e1 +.MODEL LTRA_T_pz_d1_m2_e1 LTRA( R=0.0 L= 2.522262E-07 C= 9.925464E-11 LEN= 1.000000E+00 ) +* +* Delay line for negative z propagation +* +O_T_mz_d1_m2_e2 46 1 49 1 LTRA_T_mz_d1_m2_e2 +.MODEL LTRA_T_mz_d1_m2_e2 LTRA( R=0.0 L= 2.522262E-07 C= 9.925464E-11 LEN= 1.000000E+00 ) +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m2_e1 47 1 5.041035E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m2_e2 46 1 5.041035E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m2_e1 48 50 25 1 2.000000E+00 +E_m_pz_d1_m2_e2 50 1 44 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m2_e1 49 51 31 1 2.000000E+00 +E_m_mz_d1_m2_e2 51 1 45 1 -1.000000E+00 +* +.ends +* diff --git a/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_PSpice.lib b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_PSpice.lib new file mode 100644 index 0000000..816f536 --- /dev/null +++ b/MOD_WEB_EXAMPLES/SPICE/ZT_FD_Twinax_PSpice.lib @@ -0,0 +1,216 @@ +* Pspice multi-conductor transmission line model +* +* Created by SACAMOS (State-of-the-Art CAble MOdels for Spice) +* Spice cable model builder v4.0.0 +* www.sacamos.org +* +* +* Transmission line subcircuit +* +* +* End 1 nodes: +* +* node: 2 Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 +* node: 3 Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 +* node: 4 Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield +* +* End 2 nodes: +* +* node: 5 Conductor number 1. Cable name: twinax_cable. type: twinax. conductor 1 : Twinax inner wire 1 +* node: 6 Conductor number 2. Cable name: twinax_cable. type: twinax. conductor 2 : Twinax inner wire 2 +* node: 7 Conductor number 3. Cable name: twinax_cable. type: twinax. conductor 3 : Shield +* +.subckt ZT_FD_Twinax ++ 2 3 4 ++ 5 6 7 +* +* D.C. RESISTANCE END 1 +* +Rdc_c1_e1 2 8 5.092958E-02 +Rdc_c2_e1 3 9 5.092958E-02 +Rdc_c3_e1 4 1 5.000000E-02 +* +* D.C. RESISTANCE END 2 +* +Rdc_c1_e2 5 10 5.092958E-02 +Rdc_c2_e2 6 11 5.092958E-02 +Rdc_c3_e2 7 1 5.000000E-02 +* +* DOMAIN TRANSFORMATION END 1 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e1 8 14 +Vmeas_domain_decomp_c2_e1 9 16 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e1 14 15 12 1 1.000000E+00 +E_domain_decomp_c1_dc2_e1 15 1 13 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e1 16 17 12 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e1 17 1 13 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e1 1 12 Vmeas_domain_decomp_c1_e1 1.000000E+00 +F_domain_decomp_c2_dc1_e1 1 12 Vmeas_domain_decomp_c2_e1 0.000000E+00 +F_domain_decomp_c1_dc2_e1 1 13 Vmeas_domain_decomp_c1_e1 0.000000E+00 +F_domain_decomp_c2_dc2_e1 1 13 Vmeas_domain_decomp_c2_e1 1.000000E+00 +* +* DOMAIN TRANSFORMATION END 2 +* +* +* Domain decomposition Voltage sources used for current sensing +* +Vmeas_domain_decomp_c1_e2 10 20 +Vmeas_domain_decomp_c2_e2 11 22 +* +* Domain decomposition Voltage controlled voltage sources (domain to conductor) +* +E_domain_decomp_c1_dc1_e2 20 21 18 1 1.000000E+00 +E_domain_decomp_c1_dc2_e2 21 1 19 1 -0.000000E+00 +E_domain_decomp_c2_dc1_e2 22 23 18 1 -0.000000E+00 +E_domain_decomp_c2_dc2_e2 23 1 19 1 1.000000E+00 +* +* Domain decomposition Current controlled current sources (conductor to domain) +* +F_domain_decomp_c1_dc1_e2 1 18 Vmeas_domain_decomp_c1_e2 1.000000E+00 +F_domain_decomp_c2_dc1_e2 1 18 Vmeas_domain_decomp_c2_e2 0.000000E+00 +F_domain_decomp_c1_dc2_e2 1 19 Vmeas_domain_decomp_c1_e2 0.000000E+00 +F_domain_decomp_c2_dc2_e2 1 19 Vmeas_domain_decomp_c2_e2 1.000000E+00 +* +* DOMAIN 1 +* +* +* Modal Decomposition +* +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e1 12 26 +Vmeas_mode_decomp_d1_c2_e1 13 28 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e1 26 27 24 1 -7.07106781E-01 +E_mode_decomp_d1_c1_m2_e1 27 1 25 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m1_e1 28 29 24 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m2_e1 29 1 25 1 7.07106781E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e1 1 24 Vmeas_mode_decomp_d1_c1_e1 -7.07106781E-01 +F_mode_decomp_d1_c2_m1_e1 1 24 Vmeas_mode_decomp_d1_c2_e1 -7.07106781E-01 +F_mode_decomp_d1_c1_m2_e1 1 25 Vmeas_mode_decomp_d1_c1_e1 -7.07106781E-01 +F_mode_decomp_d1_c2_m2_e1 1 25 Vmeas_mode_decomp_d1_c2_e1 7.07106781E-01 +* +* Modal decomposition Voltage sources used for current sensing +* +Vmeas_mode_decomp_d1_c1_e2 18 32 +Vmeas_mode_decomp_d1_c2_e2 19 34 +* +* Modal decomposition Voltage controlled voltage sources (mode to conductor) +* +E_mode_decomp_d1_c1_m1_e2 32 33 30 1 -7.07106781E-01 +E_mode_decomp_d1_c1_m2_e2 33 1 31 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m1_e2 34 35 30 1 -7.07106781E-01 +E_mode_decomp_d1_c2_m2_e2 35 1 31 1 7.07106781E-01 +* +* Modal decomposition Current controlled current sources (conductor to mode) +* +F_mode_decomp_d1_c1_m1_e2 1 30 Vmeas_mode_decomp_d1_c1_e2 -7.07106781E-01 +F_mode_decomp_d1_c2_m1_e2 1 30 Vmeas_mode_decomp_d1_c2_e2 -7.07106781E-01 +F_mode_decomp_d1_c1_m2_e2 1 31 Vmeas_mode_decomp_d1_c1_e2 -7.07106781E-01 +F_mode_decomp_d1_c2_m2_e2 1 31 Vmeas_mode_decomp_d1_c2_e2 7.07106781E-01 +* +* Modal impedance: end1 +* +RZCm_d1_m1_e1 24 36 1.106704E+02 +* +* Modal impedance: end2 +* +RZCm_d1_m1_e2 30 37 1.106704E+02 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m1_e1 36 1 38 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m1_e2 37 1 39 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m1_e1 39 1 40 1 LEN= 1.000000E+00 ++ R=0.0 L= 5.537350E-07 G=0.0 C= 4.521048E-11 +* +* Delay line for negative z propagation +* +T_mz_d1_m1_e2 38 1 41 1 LEN= 1.000000E+00 ++ R=0.0 L= 5.537350E-07 G=0.0 C= 4.521048E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m1_e1 39 1 1.106704E+02 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m1_e2 38 1 1.106704E+02 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m1_e1 40 42 24 1 2.000000E+00 +E_m_pz_d1_m1_e2 42 1 36 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m1_e1 41 43 30 1 2.000000E+00 +E_m_mz_d1_m1_e2 43 1 37 1 -1.000000E+00 +* +* Modal impedance: end1 +* +RZCm_d1_m2_e1 25 44 5.041035E+01 +* +* Modal impedance: end2 +* +RZCm_d1_m2_e2 31 45 5.041035E+01 +* +* Modal frequency dependent voltage controlled voltage source : end1 +* +E_m_d1_m2_e1 44 1 46 1 1.000000E+00 +* +* Modal frequency dependent voltage controlled voltage source : end2 +* +E_m_d1_m2_e2 45 1 47 1 1.000000E+00 +* +* Delay line for positive z propagation +* +T_pz_d1_m2_e1 47 1 48 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.522262E-07 G=0.0 C= 9.925464E-11 +* +* Delay line for negative z propagation +* +T_mz_d1_m2_e2 46 1 49 1 LEN= 1.000000E+00 ++ R=0.0 L= 2.522262E-07 G=0.0 C= 9.925464E-11 +* +* Modal impedances on modal positive z propagation delay lines +* +RZC_pz_d1_m2_e1 47 1 5.041035E+01 +* +* Modal impedances on modal negative z propagation delay lines +* +RZC_mz_d1_m2_e2 46 1 5.041035E+01 +* +* Delay line frequency dependent controlled sources for positive z propagation +* +E_m_pz_d1_m2_e1 48 50 25 1 2.000000E+00 +E_m_pz_d1_m2_e2 50 1 44 1 -1.000000E+00 +* +* Delay line frequency dependent controlled sources for negative z propagation +* +E_m_mz_d1_m2_e1 49 51 31 1 2.000000E+00 +E_m_mz_d1_m2_e2 51 1 45 1 -1.000000E+00 +* +.ends +* -- libgit2 0.21.2