cable_bundle_model_builder.F90
22.8 KB
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!
! This file is part of SACAMOS, State of the Art CAble MOdels for Spice.
! It was developed by the University of Nottingham and the Netherlands Aerospace
! Centre (NLR) for ESA under contract number 4000112765/14/NL/HK.
!
! Copyright (C) 2016-2018 University of Nottingham
!
! SACAMOS is free software: you can redistribute it and/or modify it under the
! terms of the GNU General Public License as published by the Free Software
! Foundation, either version 3 of the License, or (at your option) any later
! version.
!
! SACAMOS is distributed in the hope that it will be useful, but
! WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY
! or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
! for more details.
!
! A copy of the GNU General Public License version 3 can be found in the
! file GNU_GPL_v3 in the root or at <http://www.gnu.org/licenses/>.
!
! SACAMOS uses the EISPACK library (in /SRC/EISPACK). EISPACK is subject to
! the GNU Lesser General Public License. A copy of the GNU Lesser General Public
! License version can be found in the file GNU_LGPL in the root of EISPACK
! (/SRC/EISPACK ) or at <http://www.gnu.org/licenses/>.
!
! The University of Nottingham can be contacted at: ggiemr@nottingham.ac.uk
!
!
!
! File Contents:
! PROGRAM cable_bundle_model_builder
!
! NAME
! cable_bundle_model_builder
!
! AUTHORS
! Chris Smartt
!
! DESCRIPTION
! The cable_bundle_model_builder brings together a number of cable models, ground plane and
! overshield models with their position in the bundle cross section as required to build a model of a cable bundle.
! The output of the bundle_model_builder code is a file name.bundle which can be used to generate Spice cable bundle models
! for a particular modellling scenario using the program spice_cable_bundle_model_builder
!
! The input to the program is the name of a cablebundle specification file. A file name.bundle_spec must exist, containing
! all the data required to specify a cable bundle.
!
! The .cable files referred to in the .bundle_spec file are looked for in a directory specified in the .bundle_spec file.
! This may be the local directory (./) or another specified path. In this way the software can interact with a
! library of cable models (MOD).
!
! The output of the cable_bundle_model_builder code is a file name.bundle which can be used as an input to the
! spice_cable_bundle_model_builder software
!
! The .bundle file is placed in a directory specified in the .bundle_spec file. This may be the local directory (./)
! or another specified path. In this way the software can interact with a library of cable models (MOD).
!
! The program may be run with the cable bundle name specified in the command line i.e. 'cable_bundle_model_builder name'
! or it the name is absent from the command line, the user is prompted for the name.
!
! COMMENTS
! Update to V2
!
!
! HISTORY
!
! started 17/11/2015 CJS: STAGE_1 developments
! started 3/2/2016 CJS: STAGE_2 developments - multi-conductor bundles
! started 22/3/2016 CJS: STAGE_3 developments - multi-domain bundles (shielded cables)
! started 13/4/2016 CJS: Simplify the code and improve the notation. At this stage the format of the .bundle_spec file changed
! Shift the complex bundle building processes into BUNDLE_DOMAIN_CREATION/create_global_domain_structure.F90
! 20/4/2016 CJS: Allow the code to read x,y OR x, y, theta formats for cable position and orientation. Similar for ground plane
! 27/4/2016 CJS: Include a conductor based impedance (loss) model
! 29/6/2016 CJS: Check that the cables are all on one side of the ground plane if it is present
! December 2016 CJS Version 2: Rationalise cable types so that there is only a single version of each type of cable
! 24/2/2017 CJS Allow the input name to include a path i.e. the _spec file does not need to be local.
! 13/3/2018 CJS Add flag for direct/ iterative matrix solver in Laplace solution and inf/finite ground plane
! 19/6/2018 CJS Add flag for Neumann/ Asymptotic boundary condition in Laplace solver. Default is Neumann
!
! 23/10/2023 CJS Add FastHenry2 inductance matrix calculations
!
PROGRAM cable_bundle_model_builder
USE type_specifications
USE general_module
USE constants
USE cable_module
USE cable_bundle_module
USE PUL_parameter_module
USE filter_module
USE maths
USE bundle_domain_creation
IMPLICIT NONE
! local variables
! command line argument value and length if it exists
character(len=filename_length) :: argument1
integer :: argument1_length
character(len=filename_length) :: bundle_name_with_path ! name of the bundle including the path
character(len=filename_length) :: bundle_path ! path to the bundle_spec file
character(len=filename_length) :: bundle_name ! name of the bundle
character(len=filename_length) :: filename ! filename of the .bundle_spec file
! structure for the bundle specification (see CABLE_BUNDLE_MODULES/cable_bundle_module.F90)
type(bundle_specification_type) ::bundle_spec
logical :: file_exists
character(len=line_length) :: line
character(len=line_length) :: stripped_line
integer :: ierr,ierr2 ! integers to return error codes from file reads
! loop variables
integer :: cable
integer :: domain
integer :: dim
logical :: must_use_laplace
! START
program_name="cable_bundle_model_builder"
run_status='Started'
CALL write_program_status()
CALL read_version()
CALL write_license()
! Open the input file describing the cable bundle parameters
! This file could be created by the associated GUI or otherwise generated
CALL get_command_argument(1 , argument1, argument1_length)
if (argument1_length.NE.0) then
bundle_name_with_path=trim(argument1)
else
write(*,*)'Enter the name of the cable bundle specification data (without .bundle_spec extension)'
read(*,'(A)')bundle_name_with_path
end if
CALL strip_path(bundle_name_with_path,bundle_path,bundle_name)
filename=trim(bundle_name_with_path)//bundle_spec_file_extn
inquire(file=trim(filename),exist=file_exists)
if (.NOT.file_exists) then
run_status='ERROR Cannot find the file:'//trim(filename)
CALL write_program_status()
STOP 1
end if
! set the version tag in the cable_bundle structure
bundle_spec%version=SPICE_CABLE_MODEL_BUILDER_version
! open and read the .bundle_spec file
OPEN(unit=bundle_spec_file_unit,file=filename)
write(*,*)'Opened file:',trim(filename)
! set the bundle name to be the same as the name of the bundle specification data
bundle_spec%bundle_name=bundle_name
! read .bundle_spec file.
! read the MOD directory information for the cable and bundle models
read(bundle_spec_file_unit,*) ! comment line
read(bundle_spec_file_unit,'(A)')MOD_cable_lib_dir
CALL path_format(MOD_cable_lib_dir)
read(bundle_spec_file_unit,*) ! comment line
read(bundle_spec_file_unit,'(A)')MOD_bundle_lib_dir
CALL path_format(MOD_bundle_lib_dir)
! ensure that the paths exist
if (.NOT.path_exists(MOD_cable_lib_dir)) then
run_status='ERROR MOD_cable_lib_dir does not exist '//trim(MOD_cable_lib_dir)
CALL write_program_status()
STOP 1
end if
CALL check_and_make_path(MOD_bundle_lib_dir)
read(bundle_spec_file_unit,*,IOSTAT=ierr)bundle_spec%n_cables
if (ierr.NE.0) then
run_status='ERROR reading bundle_spec%n_cables '
CALL write_program_status()
STOP 1
end if
! Allocate the cable based data structures including an additional cable for the ground plane if required
ALLOCATE( bundle_spec%cable(1:bundle_spec%n_cables+1) )
ALLOCATE( bundle_spec%cable_x_offset(1:bundle_spec%n_cables+1) )
ALLOCATE( bundle_spec%cable_y_offset(1:bundle_spec%n_cables+1) )
ALLOCATE( bundle_spec%cable_angle(1:bundle_spec%n_cables+1) )
! read the name (which indicates the name.cable file specifying the cable)
! and position in the x-y bundle cross section of each cable
do cable=1,bundle_spec%n_cables
read(bundle_spec_file_unit,'(A)',IOSTAT=ierr)bundle_spec%cable(cable)%cable_name
if (ierr.NE.0) then
run_status='ERROR reading bundle_spec%cable(cable)%cable_name '
CALL write_program_status()
STOP 1
end if
read(bundle_spec_file_unit,'(A)',IOSTAT=ierr)line
read(line,*,IOSTAT=ierr)bundle_spec%cable_x_offset(cable), &
bundle_spec%cable_y_offset(cable), &
bundle_spec%cable_angle(cable)
if (ierr.NE.0) then
! Try reading the old format, set angle to zero and read x and y only
bundle_spec%cable_angle(cable)=0d0
read(line,*,IOSTAT=ierr2)bundle_spec%cable_x_offset(cable), &
bundle_spec%cable_y_offset(cable)
if (ierr2.NE.0) then
run_status='ERROR reading bundle_spec%cable_x_offset(cable),bundle_spec%cable_y_offset(cable)'
CALL write_program_status()
STOP 1
end if
end if
bundle_spec%cable_angle(cable)=bundle_spec%cable_angle(cable)*pi/180d0 ! convert angle to radians
end do ! read the informaton for the next cable
! read ground plane specification (if it exists, if it is absent then assume we have no ground plane)
read(bundle_spec_file_unit,'(A)',IOSTAT=ierr)line
if (ierr.NE.0) then
run_status='ERROR reading ground plane present/ absent information'
CALL write_program_status()
STOP 1
end if
CALL convert_to_lower_case(line,line_length)
bundle_spec%n_cables_without_ground_plane=bundle_spec%n_cables
! if (line.eq.'ground_plane') then
if (index(line,'ground_plane').EQ.1) then
bundle_spec%ground_plane_present=.TRUE.
! include an additional cable in the cable list for the ground plane (space for this is already allocated)
bundle_spec%n_cables=bundle_spec%n_cables+1
cable=bundle_spec%n_cables
! We now assume that the ground plane is along the x axis in the bundle cross section
! set x, y, theta, angle and offset to 0
bundle_spec%ground_plane_x=0d0
bundle_spec%ground_plane_y=0d0
bundle_spec%ground_plane_theta=0d0
bundle_spec%ground_plane_angle=pi/2d0
bundle_spec%ground_plane_nx=cos(bundle_spec%ground_plane_angle)
bundle_spec%ground_plane_ny=sin(bundle_spec%ground_plane_angle)
bundle_spec%ground_plane_offset=bundle_spec%ground_plane_nx*bundle_spec%ground_plane_x+ &
bundle_spec%ground_plane_ny*bundle_spec%ground_plane_y
! copy to cable structure
bundle_spec%cable_x_offset(cable)=bundle_spec%ground_plane_x
bundle_spec%cable_y_offset(cable)=bundle_spec%ground_plane_y
bundle_spec%cable_angle(cable)=bundle_spec%ground_plane_theta
! Attempt to read additional parameters for FastHenry2 calculation, sigma, width, thickness
stripped_line=line(13:line_length)
read(stripped_line,*,ERR=100,END=100)bundle_spec%ground_plane_sigma &
,bundle_spec%ground_plane_w &
,bundle_spec%ground_plane_h &
,bundle_spec%ground_plane_nsegx &
,bundle_spec%ground_plane_nsegz &
,bundle_spec%ground_plane_nh
bundle_spec%ground_plane_Rdc=1d0/(bundle_spec%ground_plane_sigma*bundle_spec%ground_plane_w*bundle_spec%ground_plane_h)
! create conductor impedance model for the new cable
ALLOCATE(bundle_spec%cable(cable)%conductor_impedance(1:1))
bundle_spec%cable(cable)%conductor_impedance(1)%impedance_model_type=impedance_model_type_FH2
bundle_spec%cable(cable)%conductor_impedance(1)%Resistance_multiplication_factor=1d0
bundle_spec%cable(cable)%conductor_impedance(1)%radius=0d0
bundle_spec%cable(cable)%conductor_impedance(1)%conductivity=bundle_spec%ground_plane_sigma
bundle_spec%cable(cable)%conductor_impedance(1)%width=bundle_spec%ground_plane_w
bundle_spec%cable(cable)%conductor_impedance(1)%height=bundle_spec%ground_plane_h
bundle_spec%cable(cable)%conductor_impedance(1)%Rdc=bundle_spec%ground_plane_Rdc
GOTO 200
100 CONTINUE ! jump here if we have failed to read FastHenry2 parameters
! create conductor impedance model for the new cable
ALLOCATE(bundle_spec%cable(cable)%conductor_impedance(1:1))
bundle_spec%cable(cable)%conductor_impedance(1)%impedance_model_type=impedance_model_type_PEC
bundle_spec%cable(cable)%conductor_impedance(1)%Resistance_multiplication_factor=1d0
bundle_spec%cable(cable)%conductor_impedance(1)%radius=0d0
bundle_spec%cable(cable)%conductor_impedance(1)%conductivity=0d0
bundle_spec%cable(cable)%conductor_impedance(1)%width=0d0
bundle_spec%cable(cable)%conductor_impedance(1)%height=0d0
bundle_spec%cable(cable)%conductor_impedance(1)%Rdc=0d0
bundle_spec%ground_plane_sigma=0d0
bundle_spec%ground_plane_w=0d0
bundle_spec%ground_plane_h=0d0
bundle_spec%ground_plane_Rdc=0d0
bundle_spec%ground_plane_nsegx=0
bundle_spec%ground_plane_nsegz=0
bundle_spec%ground_plane_nh=0
200 CONTINUE ! jump here if we do have FastHenry2 parameters
else if (line.eq.'no_ground_plane') then
bundle_spec%ground_plane_present=.FALSE. ! no ground plane present
! set x, y, theta, angle and offset to 0
bundle_spec%ground_plane_x=0d0
bundle_spec%ground_plane_y=0d0
bundle_spec%ground_plane_theta=0d0
bundle_spec%ground_plane_angle=0d0
bundle_spec%ground_plane_offset=0d0
else ! no ground plane information was given
bundle_spec%ground_plane_present=.FALSE. ! no ground plane present
! go back one line of the input file before continuing to read the .bundle_spec file
backspace(unit=bundle_spec_file_unit)
end if ! ground plane
! Set deafult propagation correction transfer function fit information
bundle_spec%Y_fit_model_order=0
CALL reset_frequency_specification(bundle_spec%Y_fit_freq_spec)
CALL set_up_frequency_specification(bundle_spec%Y_fit_freq_spec)
! Read the optional propagation correction transfer function fit information
read(bundle_spec_file_unit,*,IOSTAT=ierr)bundle_spec%Y_fit_model_order
if (ierr.NE.0) then
! Assume there is no filter fit information specified so move on to the next stage
backspace(bundle_spec_file_unit)
goto 300
end if
write(*,*)'Reading the filter fit frequency range'
CALL read_and_set_up_frequency_specification(bundle_spec%Y_fit_freq_spec,bundle_spec_file_unit)
300 continue
! the file can contain flags to control the running of the software and the output
rewind(bundle_spec_file_unit)
write(*,*)'Processing flags'
do
read(bundle_spec_file_unit,'(A)',END=310,ERR=310)line
CALL convert_to_lower_case(line,line_length)
! Set flags according to the information at the end of the .spice_model_spec file
if (INDEX(line,'verbose').NE.0) verbose=.TRUE.
if (INDEX(line,'use_s_xfer').NE.0) use_s_xfer=.TRUE.
if (INDEX(line,'no_s_xfer').NE.0) use_s_xfer=.FALSE.
if (INDEX(line,'use_laplace').NE.0) use_Laplace=.TRUE.
if (INDEX(line,'no_laplace').NE.0) use_Laplace=.FALSE.
if (INDEX(line,'plot_potential').NE.0) plot_potential=.TRUE.
if (INDEX(line,'no_plot_potential').NE.0) plot_potential=.FALSE.
if (INDEX(line,'plot_mesh').NE.0) plot_mesh=.TRUE.
if (INDEX(line,'no_plot_mesh').NE.0) plot_mesh=.FALSE.
if (INDEX(line,'direct_solver').NE.0) direct_solver=.TRUE.
if (INDEX(line,'iterative_solver').NE.0) direct_solver=.FALSE.
if (INDEX(line,'inf_gnd').NE.0) inf_gnd=.TRUE.
if (INDEX(line,'finite_gnd').NE.0) inf_gnd=.FALSE.
if (INDEX(line,'abc').NE.0) use_ABC=.TRUE.
if (INDEX(line,'neumann').NE.0) use_ABC=.FALSE.
! redefine mesh generation parameters if required
if (INDEX(line,'laplace_boundary_constant').NE.0) then
read(bundle_spec_file_unit,*,END=9000,ERR=9000)Laplace_boundary_constant
end if
if (INDEX(line,'laplace_surface_mesh_constant').NE.0) then
read(bundle_spec_file_unit,*,END=9000,ERR=9000)Laplace_surface_mesh_constant
end if
if (INDEX(line,'twisted_pair_equivalent_radius').NE.0) then
read(bundle_spec_file_unit,*,END=9000,ERR=9000)Twisted_pair_equivalent_radius
end if
if (INDEX(line,'max_mesh_edge_length').NE.0) then
read(bundle_spec_file_unit,*,END=9000,ERR=9000)max_mesh_edge_length
end if
if (INDEX(line,'gp_edge_length').NE.0) then
read(bundle_spec_file_unit,*,END=9000,ERR=9000)gp_edge_length
end if
if (INDEX(line,'cg_tol').NE.0) then
read(bundle_spec_file_unit,*,END=9000,ERR=9000)cg_tol
end if
if (INDEX(line,'no_fasthenry').NE.0) use_FastHenry=.FALSE.
if (INDEX(line,'use_fasthenry').EQ.1) then
use_FastHenry=.TRUE.
stripped_line=line(14:line_length)
read(stripped_line,*,ERR=305,END=305)FH2_nlayers_radius,FH2_nw,FH2_nh,FH2_rw,FH2_rh
if(INDEX(line,'auto_cyl_grid').NE.0) then
auto_cyl_grid=.TRUE.
end if
if(INDEX(line,'no_refinement').NE.0) then
fh2_no_refinement=.TRUE.
end if
write(*,*)'use_FastHenry=.TRUE.'
write(*,*)'Parameters:',FH2_nlayers_radius,FH2_nw,FH2_nh,FH2_rw,FH2_rh
write(*,*)'auto_cyl_grid :',auto_cyl_grid
write(*,*)'fh2_no_refinement:',fh2_no_refinement
305 CONTINUE
end if
if (INDEX(line,'l_from_fasthenry').NE.0) L_from_fasthenry=.TRUE.
end do ! continue until all flags are read - indicated by an end of file.
310 CONTINUE
! close the bundle_spec file
CLOSE(unit=bundle_spec_file_unit)
write(*,*)'Closed file:',trim(filename)
if (use_FastHenry) use_Laplace=.TRUE. ! We must use the Laplace solver too before we run FastHenry2 so set this flag
write(*,*)'Total number of cables (including ground plane):',bundle_spec%n_cables
write(*,*)'Number of cables (not including ground plane) :',bundle_spec%n_cables_without_ground_plane
! read the .cable files required to build the bundle
! Also check which cable types need to use the Laplace solver in the external domain
must_use_laplace=.FALSE.
do cable=1,bundle_spec%n_cables_without_ground_plane
CALL read_cable( bundle_spec%cable(cable),cable_file_unit)
if ( (bundle_spec%cable(cable)%cable_type.EQ.cable_geometry_type_flex_cable) &
.OR.(bundle_spec%cable(cable)%cable_type.EQ.cable_geometry_type_ML_flex_cable) ) then
must_use_laplace=.TRUE.
end if
if ( (bundle_spec%cable(cable)%cable_type.EQ.cable_geometry_type_dconnector) &
.AND.(bundle_spec%n_cables.GT.1) ) then
must_use_laplace=.TRUE.
end if
end do ! read the next cable file in the bundle
! 15/11/2023: Check for the special case of a tristed pair in free space which needs
! a special process...
if (bundle_spec%n_cables.Eq.1) then
cable=1
if (bundle_spec%cable(cable)%cable_type.EQ.cable_geometry_type_twisted_pair) then
run_status='ERROR: twisted pair cable in free space with no other conductors. Model this using two cylindrical wires'
CALL write_program_status()
STOP 1
end if
end if
! Check whether Laplace solver must be used
if (must_use_laplace.AND.(.NOT.use_Laplace)) then
run_status='ERROR: The laplace solver must be used for this cable bundle.'
CALL write_program_status()
STOP 1
end if
! set the ground plane cable data (if it is present)
if (bundle_spec%ground_plane_present) then
cable=bundle_spec%n_cables
bundle_spec%cable(cable)%version=SPICE_CABLE_MODEL_BUILDER_version
bundle_spec%cable(cable)%cable_name='ground plane'
bundle_spec%cable(cable)%cable_type_string='ground_plane'
bundle_spec%cable(cable)%cable_type=cable_geometry_type_ground_plane
CALL ground_plane_set_parameters(bundle_spec%cable(cable))
CALL ground_plane_set_internal_domain_information(bundle_spec%cable(cable))
! check that all the conductors are on one side of the ground plane
CALL check_cables_wrt_ground_plane(bundle_spec)
end if
! Write the bundle cross section (condcutors and dielectrics) to files suitable for gnuplot
CALL plot_bundle_cross_section(bundle_spec)
! check whether there is any intersection between cables
CALL check_cable_intersection(bundle_spec)
! now we have the complete bundle specification information we can go and build the bundle structure
CALL create_global_domain_structure(bundle_spec)
! Create the arrays of x and y coordinates of each conductor which are used in the incident field excitation
! moved from before create_global_domain_structure
CALL set_conductor_positions_for_Einc(bundle_spec)
if (verbose) then
! Write the .bundle structure to screen
write(*,*)'____________________________________________'
write(*,*)''
write(*,*)'Domain inductance matrices [L]'
write(*,*)''
do domain=1,bundle_spec%tot_n_domains
write(*,*)'Domain=',domain,' matrix dimension=',bundle_spec%L(domain)%dim
dim=bundle_spec%L(domain)%dim
CALL dwrite_matrix(bundle_spec%L(domain)%mat,dim,dim,dim,0)
end do
write(*,*)'____________________________________________'
write(*,*)''
write(*,*)'Domain capacitance matrices [C]'
write(*,*)''
do domain=1,bundle_spec%tot_n_domains
write(*,*)'Domain=',domain,' matrix dimension=',bundle_spec%C(domain)%dim
dim=bundle_spec%C(domain)%dim
CALL dwrite_matrix(bundle_spec%C(domain)%mat,dim,dim,dim,0)
end do
write(*,*)'____________________________________________'
write(*,*)''
write(*,*)'Global external to domain conductor current transformation matrix, [MI]'
write(*,*)''
dim=bundle_spec%global_MI%dim
CALL dwrite_matrix(bundle_spec%global_MI%mat,dim,dim,dim,0)
write(*,*)'____________________________________________'
write(*,*)''
write(*,*)'Global external to domain conductor voltage transformation matrix, [MV]'
write(*,*)''
dim=bundle_spec%global_MV%dim
CALL dwrite_matrix(bundle_spec%global_MV%mat,dim,dim,dim,0)
write(*,*)'____________________________________________'
write(*,*)''
write(*,*)'Global Inductance matrix, [L]'
write(*,*)''
dim=bundle_spec%global_L%dim
CALL dwrite_matrix(bundle_spec%global_L%mat,dim,dim,dim,0)
write(*,*)'____________________________________________'
write(*,*)''
write(*,*)'Global Capacitance matrix, [C]'
write(*,*)''
dim=bundle_spec%global_C%dim
CALL dwrite_matrix(bundle_spec%global_C%mat,dim,dim,dim,0)
end if ! verbose
CALL write_cable_bundle(bundle_spec,bundle_file_unit)
CALL deallocate_frequency_specification(bundle_spec%Y_fit_freq_spec)
CALL deallocate_cable_bundle(bundle_spec)
! finish up
run_status='Finished_Correctly'
CALL write_program_status()
STOP
9000 run_status='ERROR reading control parameter from the bundle_spec file'
CALL write_program_status()
STOP 1
END PROGRAM cable_bundle_model_builder