!
! This file is part of SACAMOS, State of the Art CAble MOdels in 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) 2016-2017 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 .
!
! 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 .
!
! The University of Nottingham can be contacted at: ggiemr@nottingham.ac.uk
!
! NAME
! SUBROUTINE create_global_domain_structure
!
! DESCRIPTION
! The processes implemented in this subroutine calculate the matrices which are required to
! characterise the multi-conductor cable propagation in both a local, domain based system for the Spice model development
! and in a global basis for analysis of the bundle as a whole for the validation test circuit.
! The matrices characterising the propagation are :
! the domain based 'high frequency' L and C matrices,
! the domain based frequency dependent Z and Y matrices,
! the global 'high frequency' L and C matrices,
! the global frequency dependent Z and Y matrices,
! the voltage and current domain decomposition matrices MI and MV
!
! For shielded domains the L, C, Z, and Y matrices are known from the cable data structures
! For any overshield domains and the external domain these matrices are calculated here via
! calls to the appopriate PUL calculation subroutines
!
! The processes implemented in this subroutine are summarised as follows:
!
! 1. Count the total number of conductors in the bundle and Allocate and reset the local data structures
! 2. Loop over the cables filling the referencing arrays with local information
! 3. For each cable, work out which domain it is in and hence its reference conductor number.
! 4. Count the number of conductors in the external domain to check whether it is viable i.e. at least 2 conductors
! 5. build the global_domain numbering, ignoring any unused domains
! 6. build the domain based L and C matrices plus the global MI and MV matrices and the global L and C matrices
! 7. Calculate the inductance and capacitance matrices for the external domains (domains within overshields and the external domain)
! 8. Copy the cable based conductor impedance (loss) models to the bundle structure
! 8b. Copy the cable based conductor labels to the bundle structure
! 9 save numbering information required for the transfer impedance calculation
! 10. deallocate local memory
!
! COMMENTS
!
!
! HISTORY
! started 2/12/2015 CJS
! 27/4/2016 CJS: Include a conductor based impedance (loss) model
! 24/5/2016 CJS: Fix errors in MI and MV matrices for multi-conductor overshield domains
! 7/7/2016 CJS: Allow the use of the Laplace solver for L,C,G matrix calculation in external and overshield domains.
! 9/9/2016 CJS: Fix problem with MV and MI matrix for the twisted pair model. Elements were being overwritten incorrectly.
! when adding the external conductor contribution to the domain decomposition matrices
! 4/10/2016 CJS: Save the local domain conductor numbering
! 17/5/2017 CJS: Work out which domains are Shielded Twisted Pair differential mode domains and flag these
! so that we can work out the is_shield flag properly in all circumstances.
! 18/10/2017 CJS: include 8b. Copy the cable based conductor labels to the bundle structure
! 16/11/2017 CJS Include network synthesis process to replace s-domain transfer functions
!
SUBROUTINE create_global_domain_structure(bundle)
USE type_specifications
USE general_module
USE constants
USE cable_module
USE cable_bundle_module
USE PUL_parameter_module
USE filter_module
USE maths
IMPLICIT NONE
! variables passed to subroutine
type(bundle_specification_type),intent(INOUT) :: bundle
! local variables
! global cable, conductor and domain numbers and loop variables
integer :: cable
integer :: tot_n_cables
integer :: tot_n_cables_without_ground_plane
integer :: tot_n_conductors,conductor,conductor_count,terminal_conductor
integer :: tot_n_domains,tot_n_viable_domains,domain,domain_count
integer :: tot_n_internal_domains
! local conductor and domain numbers and loop variables
integer :: local_n_conductors,local_conductor,n_cable_conductors
integer :: local_cable_conductor,local_domain_conductor
integer :: local_n_domains,local_domain
integer :: first_external_domain
integer :: reference_conductor
integer :: first_external_conductor
! variables for looking at overshields and determining which domain cables are in
integer :: tot_n_overshields,n_overshield_domains,overshield
integer,allocatable :: overshield_shape(:)
real(dp),allocatable :: overshield_x(:)
real(dp),allocatable :: overshield_y(:)
real(dp),allocatable :: overshield_r(:)
real(dp),allocatable :: overshield_w(:)
real(dp),allocatable :: overshield_w2(:)
real(dp),allocatable :: overshield_h(:)
integer,allocatable :: overshield_domain(:)
integer,allocatable :: overshield_reference_terminal_conductor(:)
integer,allocatable :: overshield_n_conductors(:)
integer,allocatable :: overshield_terminal_conductor(:,:)
real(dp) :: cable_x,cable_y,dist_cable_to_overshield_centre
logical :: is_overshield_domain
! referencing arrays
integer,allocatable :: terminal_conductor_to_cable(:)
integer,allocatable :: terminal_conductor_to_cable_local_domain(:)
integer,allocatable :: terminal_conductor_to_global_domain(:)
integer,allocatable :: terminal_conductor_to_global_domain_conductor(:)
integer,allocatable :: terminal_conductor_to_reference_global_domain_conductor(:)
integer,allocatable :: terminal_conductor_to_reference_terminal_conductor(:)
integer,allocatable :: global_domain_conductor_to_terminal_conductor(:)
logical,allocatable :: terminal_conductor_is_reference_conductor(:)
logical,allocatable :: domain_is_TP_differential_mode(:)
integer,allocatable :: cable_reference_domain(:)
integer,allocatable :: cable_reference_conductor(:)
integer,allocatable :: external_terminal_conductor(:)
logical :: is_external_domain
integer :: external_conductor_count
integer,allocatable :: global_domain_reference_conductor(:)
! structure used by the Per-Unit-Length parameter calculation for overshield and external domains
type(PUL_type) :: PUL
! loop variables for matrix operations
integer :: dim
integer :: row,col
integer :: row_l,col_l
integer :: row_g,col_g
character(LEN=3) :: conductor_string ! used to generate the conductor labels in the bundle
! START
if(verbose) write(*,*)'CALLED: create_global_domain_structure'
! Copy some data to local variables for clarity of notation
tot_n_cables=bundle%n_cables
if (bundle%ground_plane_present) then
tot_n_cables_without_ground_plane=tot_n_cables-1
else
tot_n_cables_without_ground_plane=tot_n_cables
end if
if(verbose) write(*,*)' Total number of cables=',tot_n_cables
if(verbose) write(*,*)' Total number of cables not including ground plane=',tot_n_cables_without_ground_plane
! 1a. Count the total number of conductors in the bundle
tot_n_conductors=0
do cable=1,tot_n_cables
tot_n_conductors = tot_n_conductors + bundle%cable(cable)%tot_n_conductors
end do
if(verbose) write(*,*)' Total number of conductors=',tot_n_conductors
bundle%tot_n_conductors=tot_n_conductors
bundle%system_dimension=tot_n_conductors-1
! 1b Allocate and reset the local data structures
ALLOCATE( terminal_conductor_to_cable(1:tot_n_conductors) )
ALLOCATE( terminal_conductor_to_cable_local_domain(1:tot_n_conductors) )
ALLOCATE( terminal_conductor_to_global_domain(1:tot_n_conductors) )
ALLOCATE( terminal_conductor_to_global_domain_conductor(1:tot_n_conductors) )
ALLOCATE( terminal_conductor_to_reference_global_domain_conductor(1:tot_n_conductors) )
ALLOCATE( terminal_conductor_to_reference_terminal_conductor(1:tot_n_conductors) )
ALLOCATE( terminal_conductor_is_reference_conductor(1:tot_n_conductors) )
ALLOCATE( global_domain_conductor_to_terminal_conductor(1:tot_n_conductors) )
terminal_conductor_to_cable(1:tot_n_conductors)=0
terminal_conductor_to_cable_local_domain(1:tot_n_conductors)=0
terminal_conductor_to_global_domain(1:tot_n_conductors)=0
terminal_conductor_to_global_domain_conductor(1:tot_n_conductors)=0
terminal_conductor_to_reference_global_domain_conductor(1:tot_n_conductors)=0
terminal_conductor_to_reference_terminal_conductor(1:tot_n_conductors)=0
terminal_conductor_is_reference_conductor(1:tot_n_conductors)=.FALSE.
global_domain_conductor_to_terminal_conductor(1:tot_n_conductors)=0
! numbering information required for the transfer impedance calculation
ALLOCATE( bundle%terminal_conductor_is_shield_flag(1:bundle%tot_n_conductors) )
ALLOCATE( bundle%terminal_conductor_to_inner_domain(1:bundle%tot_n_conductors) )
ALLOCATE( bundle%terminal_conductor_to_outer_domain(1:bundle%tot_n_conductors) )
ALLOCATE( bundle%terminal_conductor_to_global_domain_conductor(1:bundle%tot_n_conductors) )
ALLOCATE( bundle%terminal_conductor_to_local_domain_conductor(1:bundle%tot_n_conductors) )
ALLOCATE( bundle%terminal_conductor_to_reference_terminal_conductor(1:bundle%tot_n_conductors) )
bundle%terminal_conductor_is_shield_flag(1:bundle%tot_n_conductors)=.FALSE.
bundle%terminal_conductor_to_inner_domain(1:bundle%tot_n_conductors)=0
bundle%terminal_conductor_to_outer_domain(1:bundle%tot_n_conductors)=0
bundle%terminal_conductor_to_global_domain_conductor(1:bundle%tot_n_conductors)=0
bundle%terminal_conductor_to_local_domain_conductor(1:bundle%tot_n_conductors)=0
bundle%terminal_conductor_to_reference_terminal_conductor(1:bundle%tot_n_conductors)=0
! 2. Loop over the cables filling the referencing arrays with local information
! Also count the total number of internal domains in the bundle
conductor=0
tot_n_domains=0
do cable=1,tot_n_cables
local_n_domains=bundle%cable(cable)%tot_n_domains
tot_n_domains=tot_n_domains+bundle%cable(cable)%n_internal_domains
do local_domain=1,local_n_domains
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_conductor=1,local_n_conductors
conductor=conductor+1
terminal_conductor_to_cable(conductor)=cable
terminal_conductor_to_cable_local_domain(conductor)=local_domain
end do
end do ! next conductor in this cable
end do
tot_n_internal_domains=tot_n_domains
first_external_domain=tot_n_domains+1
if(verbose) then
write(*,*)'Total number of internal domains=',tot_n_domains
write(*,*)'First external domain=',first_external_domain
end if
! check counting...
if (conductor.NE.tot_n_conductors) then
run_status='ERROR in create_global_domain_structure: last conductor.NE.tot_n_conductors'
CALL write_program_status()
STOP 1
end if
! 3. For each cable, work out which domain it is in and hence its reference conductor number.
! 3a. first count the overshields
tot_n_overshields=0
do cable=1,tot_n_cables
if (bundle%cable(cable)%cable_type.EQ.cable_geometry_type_overshield) then
tot_n_overshields=tot_n_overshields+1
end if
end do
if(verbose) write(*,*)'Total number of over-shields=',tot_n_overshields
! 3b. Get the position of the overshields
if (tot_n_overshields.GT.0) then
ALLOCATE( overshield_shape(1:tot_n_overshields) )
ALLOCATE( overshield_x(1:tot_n_overshields) )
ALLOCATE( overshield_y(1:tot_n_overshields) )
ALLOCATE( overshield_r(1:tot_n_overshields) )
ALLOCATE( overshield_w(1:tot_n_overshields) )
ALLOCATE( overshield_w2(1:tot_n_overshields) )
ALLOCATE( overshield_h(1:tot_n_overshields) )
ALLOCATE( overshield_reference_terminal_conductor(1:tot_n_overshields) )
overshield=0
conductor_count=0
do cable=1,tot_n_cables
if (bundle%cable(cable)%cable_type.EQ.cable_geometry_type_overshield) then
overshield=overshield+1
overshield_shape(overshield)=circle
overshield_x(overshield)=bundle%cable_x_offset(cable)
overshield_y(overshield)=bundle%cable_y_offset(cable)
overshield_r(overshield)=bundle%cable(cable)%parameters(1) ! overshield radius
overshield_w(overshield)=0d0
overshield_w2(overshield)=0d0
overshield_h(overshield)=0d0
overshield_reference_terminal_conductor(overshield)=conductor_count+1
end if
conductor_count=conductor_count+bundle%cable(cable)%tot_n_conductors
end do
ALLOCATE( overshield_domain(1:tot_n_overshields) )
overshield_domain(1:tot_n_overshields)=0
ALLOCATE( overshield_n_conductors(1:tot_n_overshields) )
overshield_n_conductors(1:tot_n_overshields)=0
ALLOCATE( overshield_terminal_conductor(1:tot_n_overshields,1:tot_n_conductors) ) ! over the top memory allocation here but simpler this way
overshield_terminal_conductor(1:tot_n_overshields,1:tot_n_conductors)=0
end if ! n_overshields.GT.0
! allocate array for domain reference conductors assuming worst case that all overshields and external domain are viable
ALLOCATE( global_domain_reference_conductor(1:tot_n_domains+tot_n_overshields+1) )
global_domain_reference_conductor(1:tot_n_domains+tot_n_overshields+1)=0
! 3c. Loop over cables and see whether it sits within an overshield or not
ALLOCATE( cable_reference_domain(1:bundle%n_cables) )
cable_reference_domain(1:bundle%n_cables)=0
ALLOCATE( cable_reference_conductor(1:bundle%n_cables) )
cable_reference_conductor(1:bundle%n_cables)=0
n_overshield_domains=0 ! counter for overshield domains
do cable=1,tot_n_cables
if (bundle%cable(cable)%cable_type.NE.cable_geometry_type_overshield) then
! if this cable is not an overshield then see whether it is WITHIN an overshield
cable_x=bundle%cable_x_offset(cable)
cable_y=bundle%cable_y_offset(cable)
do overshield=1,tot_n_overshields
dist_cable_to_overshield_centre=sqrt( (cable_x-overshield_x(overshield))**2+ &
(cable_y-overshield_y(overshield))**2 )
if ( dist_cable_to_overshield_centre.LT.overshield_r(overshield) ) then
! we conclude that this cable is with the overshield
if (overshield_domain(overshield).EQ.0) then
! this overshield domain is unallocated so create a new domain
tot_n_domains=tot_n_domains+1
n_overshield_domains=n_overshield_domains+1
if(verbose) write(*,*)'Creating overshield domain=',tot_n_domains
overshield_domain(overshield)=tot_n_domains
global_domain_reference_conductor(tot_n_domains)=overshield_reference_terminal_conductor(overshield)
end if ! this overshield domain is unallocated
cable_reference_domain(cable)=overshield_domain(overshield)
end if ! this cable is with the overshield
end do ! next overshield to check
terminal_conductor=terminal_conductor+bundle%cable(cable)%tot_n_conductors ! update the terminal conductor count
end if ! not an overshield
end do ! next cable
if (verbose) write(*,*) 'n_overshield_domains=',n_overshield_domains
! 3c part 2. loop over the overshield domains and count the number of external conductors in each one
do overshield=1,tot_n_overshields
terminal_conductor=0 ! count the terminal conductor number
conductor_count=0 ! count the number of condcutors referenced to this overshield
do cable=1,tot_n_cables_without_ground_plane
if (cable_reference_domain(cable).EQ.overshield_domain(overshield)) then
! this cable contributes its external conductors to the overshield
first_external_conductor=terminal_conductor+bundle%cable(cable)%tot_n_conductors-bundle%cable(cable)%n_external_conductors+1
do conductor=1,bundle%cable(cable)%n_external_conductors
conductor_count=conductor_count+1
overshield_terminal_conductor(overshield,conductor_count)=first_external_conductor+(conductor-1)
end do
end if
terminal_conductor=terminal_conductor+bundle%cable(cable)%tot_n_conductors ! update the terminal conductor count
end do ! next cable
overshield_n_conductors(overshield)=conductor_count
end do ! next overshield
if (verbose) then
write(*,*)
write(*,*)'Overshield conductor information'
do overshield=1,tot_n_overshields
write(*,*)'Overshield:',overshield,' Number of condcutors=',overshield_n_conductors(overshield)
write(*,*)' Overshield_conductor terminal_conductor '
do conductor=1,overshield_n_conductors(overshield)
write(*,*)conductor,overshield_terminal_conductor(overshield,conductor)
end do
end do ! next overshield
write(*,*)
end if
! 3d. We now have unallocated reference domains, these are not in overshields so must be in the external domain
! 4. Count the number of conductors in the external domain to check whether it is viable i.e. at least 2 conductors
bundle%tot_n_external_conductors=0
do cable=1,tot_n_cables
if (cable_reference_domain(cable).EQ.0) then
! this cable reference domain must be the external domain
bundle%tot_n_external_conductors=bundle%tot_n_external_conductors+bundle%cable(cable)%n_external_conductors
end if ! reference domain not yet set
end do ! next cable
if(verbose) write(*,*)'Number of conductors in external domain=',bundle%tot_n_external_conductors
! 4b. Create an external domain and allocate unallocated reference domains now...
ALLOCATE( external_terminal_conductor(1:bundle%tot_n_external_conductors) )
external_terminal_conductor(1:bundle%tot_n_external_conductors)=0
tot_n_viable_domains=tot_n_domains
tot_n_domains=tot_n_domains+1
if (bundle%tot_n_external_conductors.GT.1) then
tot_n_viable_domains=tot_n_viable_domains+1
end if
if(verbose) write(*,*)'Creating external domain=',tot_n_domains
terminal_conductor=0
external_conductor_count=0
do cable=1,tot_n_cables
is_external_domain=.FALSE.
if (cable_reference_domain(cable).EQ.0) then ! this cable reference domain must be the external domain
cable_reference_domain(cable)=tot_n_domains
is_external_domain=.TRUE.
end if
do local_conductor=1,bundle%cable(cable)%tot_n_conductors
terminal_conductor=terminal_conductor+1
if ( (is_external_domain).AND.(bundle%cable(cable)%local_reference_conductor(local_conductor).EQ.0) ) then
external_conductor_count=external_conductor_count+1
external_terminal_conductor(external_conductor_count)=terminal_conductor
end if
end do
if (is_external_domain) then ! this cable reference domain must be the external domain
global_domain_reference_conductor(tot_n_domains)=terminal_conductor
end if
end do ! next cable
! check the conductor count
if (external_conductor_count.NE.bundle%tot_n_external_conductors) then
run_status='ERROR in create_global_domain_structure: external_conductor_count.NE.bundle%tot_n_external_conductors'
CALL write_program_status()
STOP 1
end if
if(verbose) then
write(*,*)'External domain terminal conductors:'
do conductor=1,bundle%tot_n_external_conductors
write(*,*)'conductor=',external_terminal_conductor(conductor)
end do ! next cable
end if
bundle%tot_n_domains=tot_n_viable_domains
if(verbose) then
write(*,*)'Total number of domains=',tot_n_domains
write(*,*)'Total number of viable domains=',tot_n_viable_domains
write(*,*)'Cable reference domain numbers:'
do cable=1,tot_n_cables
write(*,*)'cable=',cable,' reference domain=',cable_reference_domain(cable)
end do ! next cable
end if
ALLOCATE( domain_is_TP_differential_mode(1:tot_n_domains) )
domain_is_TP_differential_mode(1:tot_n_domains)=.FALSE.
! 5. build the global_domain numbering, ignoring any unused domains
conductor=0 ! this is the external conductor number
domain_count=0
conductor_count=0 ! this is the conductor count for the domain based numbering
! 5a. Count conductors from internal domains initially
do cable=1,tot_n_cables
local_cable_conductor=0
local_n_domains=bundle%cable(cable)%tot_n_domains
! 17/5/2017 CJS Add a check here to flag twisted pair differential mode domains
! The check is hrd wired based on cable types
if (bundle%cable(cable)%cable_type.EQ.cable_geometry_type_twisted_pair) then
domain_is_TP_differential_mode(domain_count+1)=.TRUE.
else if (bundle%cable(cable)%cable_type.EQ.cable_geometry_type_shielded_twisted_pair) then
domain_is_TP_differential_mode(domain_count+1)=.TRUE.
else if (bundle%cable(cable)%cable_type.EQ.cable_geometry_type_spacewire) then
domain_is_TP_differential_mode(domain_count+1)=.TRUE.
domain_is_TP_differential_mode(domain_count+3)=.TRUE.
domain_is_TP_differential_mode(domain_count+5)=.TRUE.
domain_is_TP_differential_mode(domain_count+7)=.TRUE.
end if
! exclude the external domain
do local_domain=1,local_n_domains
if (local_domain.NE.local_n_domains) then
! This is an internal domain so add to the domain count
domain_count=domain_count+1
domain=domain_count
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_conductor=1,local_n_conductors
conductor=conductor+1
local_cable_conductor=local_cable_conductor+1
conductor_count=conductor_count+1
terminal_conductor_to_global_domain(conductor)=domain
terminal_conductor_to_cable_local_domain(conductor)=local_conductor
terminal_conductor_to_global_domain_conductor(conductor)=conductor_count
bundle%cable(cable)%global_domain_conductor(local_cable_conductor)=conductor_count
bundle%cable(cable)%terminal_conductor(local_cable_conductor)=conductor
end do
else
! This is an external domain so leave until later but count the global conductors.
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_conductor=1,local_n_conductors
conductor=conductor+1
local_cable_conductor=local_cable_conductor+1
end do
end if ! internal or external domain
end do ! next conductor in this cable
end do ! next cable
! 5b. Include the 'external' domain conductors now
do domain=first_external_domain,tot_n_domains
conductor=0 ! this is the external conductor number
do cable=1,tot_n_cables
local_cable_conductor=0
local_n_domains=bundle%cable(cable)%tot_n_domains
do local_domain=1,local_n_domains
if (local_domain.NE.local_n_domains) then
! This is an internal domain so this is already included, only count the conductors
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_conductor=1,local_n_conductors
conductor=conductor+1
local_cable_conductor=local_cable_conductor+1
end do
else
! This is an external domain so add the conductors if it is the currrent external domain
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_conductor=1,local_n_conductors
conductor=conductor+1
local_cable_conductor=local_cable_conductor+1
if (cable_reference_domain(cable).EQ.domain) then
conductor_count=conductor_count+1
terminal_conductor_to_global_domain(conductor)=domain
terminal_conductor_to_cable_local_domain(conductor)=local_conductor
terminal_conductor_to_global_domain_conductor(conductor)=conductor_count
bundle%cable(cable)%global_domain_conductor(local_cable_conductor)=conductor_count
bundle%cable(cable)%terminal_conductor(local_cable_conductor)=conductor
end if ! this external domain is the current one to be included
end do ! next local conductor
end if ! internal or external domain
end do ! next local domain
end do ! next cable
end do ! next external domain
! 5c. Set the global_domain_conductor_to_terminal_conductor from terminal_conductor_to_global_domain_conductor
if (verbose) then
write(*,*)'conductor,terminal_conductor_to_global_domain_conductor(conductor)'
do conductor=1,tot_n_conductors
write(*,*)conductor,terminal_conductor_to_global_domain_conductor(conductor)
end do
end if
! loop over terminal conductors
do conductor=1,tot_n_conductors
global_domain_conductor_to_terminal_conductor(terminal_conductor_to_global_domain_conductor(conductor))=conductor
end do
! 5d. Set the global_domain_reference_conductor information, also flag all the reference conductors in internal domains
conductor=0 ! this is the external conductor number
write(*,*)
write(*,*)
write(*,*)' terminal cable local local_domain global cable local_ref ref terminal ref global '
write(*,*)' conductor domain conductor domain conductor conductor conductor domain conductor'
do cable=1,tot_n_cables
local_n_domains=bundle%cable(cable)%tot_n_domains
local_cable_conductor=0
do local_domain=1,local_n_domains
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_domain_conductor=1,local_n_conductors
conductor=conductor+1
local_cable_conductor=local_cable_conductor+1
reference_conductor=bundle%cable(cable)%local_reference_conductor(local_cable_conductor)
if (reference_conductor.NE.0) then
! the reference conductor is defined locally
terminal_conductor_to_reference_global_domain_conductor(conductor)= &
bundle%cable(cable)%global_domain_conductor(reference_conductor)
! 27/4/2016 CJS
domain=terminal_conductor_to_global_domain(conductor)
! 16/5/2016 this should be the global not the local number... global_domain_reference_conductor(domain)=reference_conductor
global_domain_reference_conductor(domain)=bundle%cable(cable)%global_domain_conductor(reference_conductor)
else
! the reference conductor is defined in terms of the reference domain of the cable
domain=cable_reference_domain(cable)
reference_conductor=global_domain_reference_conductor(domain)
terminal_conductor_to_reference_global_domain_conductor(conductor)= &
terminal_conductor_to_global_domain_conductor(reference_conductor)
reference_conductor=0
end if
local_conductor=terminal_conductor_to_reference_global_domain_conductor(conductor)
terminal_conductor_to_reference_terminal_conductor(conductor)= &
global_domain_conductor_to_terminal_conductor(local_conductor)
terminal_conductor_is_reference_conductor(terminal_conductor_to_reference_terminal_conductor(conductor))=.TRUE.
write(*,8000)bundle%cable(cable)%terminal_conductor(local_cable_conductor),&
cable,local_domain,local_domain_conductor, &
terminal_conductor_to_global_domain(conductor), &
local_cable_conductor,reference_conductor, &
terminal_conductor_to_reference_terminal_conductor(conductor), &
terminal_conductor_to_reference_global_domain_conductor(conductor)
8000 format(5I11,4I13)
end do ! next local domain conductor
end do ! next local domain
end do ! next cable
! 6. Now that we have counted the number of domains we can allocate the
! domain based number of conductors and L and C matrices plus
! the global MI and MV matrices
! Note: this allocation includes non-viable domains
ALLOCATE( bundle%n_conductors(1:tot_n_domains) )
bundle%n_conductors(1:tot_n_domains)=0
ALLOCATE( bundle%L(1:tot_n_domains) )
ALLOCATE( bundle%C(1:tot_n_domains) )
ALLOCATE( bundle%Z(1:tot_n_domains) )
ALLOCATE( bundle%Y(1:tot_n_domains) )
! 6a. Count the number of conductors in each domain
if (verbose) write(*,*)'terminal_conductor domain local_domain_conductor'
do conductor=1,tot_n_conductors
domain=terminal_conductor_to_global_domain(conductor)
bundle%n_conductors(domain)=bundle%n_conductors(domain)+1
! 4/10/2016 Save the local domain coonductor numbering
bundle%terminal_conductor_to_local_domain_conductor(conductor)=bundle%n_conductors(domain)
if (verbose) write(*,*)conductor,domain,bundle%terminal_conductor_to_local_domain_conductor(conductor)
end do ! next conductor
! Note there may be unviable overshield domains which need to be excluded in the following loop...
! internal domains and overshield domains don't include the reference conductor so add this here
do domain=1,tot_n_internal_domains+n_overshield_domains
bundle%n_conductors(domain)=bundle%n_conductors(domain)+1
end do
if (verbose) then
write(*,*)
write(*,*)'Number of conductors in each domain'
write(*,*)' domain n_conductors'
do domain=1,tot_n_domains
write(*,*)domain,bundle%n_conductors(domain)
end do
end if
! allocate the global voltage and current domain transformation matrices
! strictly the dimension should be bundle%tot_n_conductors-1
! this would require many checks later on to prevent array bounds problems with no ground plane specified
! so we allocate the extra space then ignore the last row and col when doing the domain decomposition
dim=bundle%tot_n_conductors
if(verbose) then
write(*,*)'ALLOCATING global_MI and global_MV, dimension:',dim
end if
bundle%global_MI%dim=dim
ALLOCATE( bundle%global_MI%mat(1:dim,1:dim) )
bundle%global_MI%mat(1:dim,1:dim)=0d0
bundle%global_MV%dim=dim
ALLOCATE( bundle%global_MV%mat(1:dim,1:dim) )
bundle%global_MV%mat(1:dim,1:dim)=0d0
! Allocate the conductor based impedance (loss) model and reset all the parameters
ALLOCATE( bundle%conductor_impedance(1:dim) )
do conductor=1,bundle%tot_n_conductors
bundle%conductor_impedance(conductor)%radius=0d0
bundle%conductor_impedance(conductor)%width=0d0
bundle%conductor_impedance(conductor)%height=0d0
bundle%conductor_impedance(conductor)%conductivity=0d0
bundle%conductor_impedance(conductor)%thickness=0d0
bundle%conductor_impedance(conductor)%Resistance_multiplication_factor=1d0
end do
! allocate the global inductance and capacitance matrices - these are used in the analytic solution
! which is used for validation
dim=bundle%tot_n_conductors-1
if(verbose) then
write(*,*)'ALLOCATING global_L and global_C, dimension:',dim
end if
bundle%global_L%dim=dim
ALLOCATE( bundle%global_L%mat(1:dim,1:dim) )
bundle%global_L%mat(1:dim,1:dim)=0d0
bundle%global_C%dim=dim
ALLOCATE( bundle%global_C%mat(1:dim,1:dim) )
bundle%global_C%mat(1:dim,1:dim)=0d0
if(verbose) then
write(*,*)'ALLOCATING global_Z and global_Y, dimension:',dim
end if
bundle%global_Z%dim=dim
ALLOCATE( bundle%global_Z%sfilter_mat(1:dim,1:dim) )
do row=1,dim
do col=1,dim
bundle%global_Z%sfilter_mat(row,col)=0d0 ! set all filters to zero filter for now
end do
end do
bundle%global_Y%dim=dim
ALLOCATE( bundle%global_Y%sfilter_mat(1:dim,1:dim) )
do row=1,dim
do col=1,dim
bundle%global_Y%sfilter_mat(row,col)=0d0 ! set all filters to zero filter for now
end do
end do
! Allocate the domain based terminal conductor list CJS 27/4/2016
ALLOCATE( bundle%terminal_conductor_list(1:bundle%tot_n_domains))
! 6b. Copy the cable based internal domain L and C matrices to bundle structure
! and construct the global MI and MV matrices from the cable based structures
terminal_conductor=0 ! this is the external conductor number
domain_count=0
do cable=1,tot_n_cables_without_ground_plane
local_n_domains=bundle%cable(cable)%tot_n_domains
local_cable_conductor=0
n_cable_conductors=bundle%cable(cable)%tot_n_conductors
! copy the cable based MI and MV matrices to the global structure. The cable based
! MI and MV matrices are on the basis of terminal_conductor numbering
if (verbose) then
write(*,*)'Copy MI, MV, cable=',cable,' of', tot_n_cables_without_ground_plane
write(*,*)'Matrix dimension',n_cable_conductors+1
write(*,*)'intial terminal_conductor count=',terminal_conductor
end if
do row_l=1,n_cable_conductors+1 ! add 1 as the reference conductor must be included
do col_l=1,n_cable_conductors+1 ! add 1 as the reference conductor must be included
! In the global MI, MV structure rows correspond to the global domain conductor number, cols correspond to the terminal conductor number
if (row_l.NE.n_cable_conductors+1) then
row_g=terminal_conductor_to_global_domain_conductor(terminal_conductor+row_l)
else
row_g=terminal_conductor_to_reference_global_domain_conductor(terminal_conductor+row_l-1) ! last conductor for this cable and the reference
end if
if (col_l.NE.n_cable_conductors+1) then
col_g=terminal_conductor+col_l
else
col_g=terminal_conductor_to_reference_terminal_conductor(terminal_conductor+col_l-1) ! last conductor for this cable and the reference
end if
bundle%global_MI%mat(row_g,col_g)=bundle%cable(cable)%MI%mat(row_l,col_l)
bundle%global_MV%mat(row_g,col_g)=bundle%cable(cable)%MV%mat(row_l,col_l)
if (verbose) write(*,*)'Copy MV element',row_g,col_g,bundle%global_MV%mat(row_g,col_g)
end do ! next col
end do ! next row
do local_domain=1,local_n_domains ! exclude the external domain for now
if (local_domain.NE.local_n_domains) then
! This is an internal domain so add to the domain count
domain_count=domain_count+1
domain=domain_count
! 6c copy the domain based L and C matrices to the domain based L and C in the bundle structure #
if (verbose) write(*,*)'Copy the domain based L and C matrices to the domain based L and C in the bundle structure'
if (verbose) write(*,*)'domain=',domain
dim=bundle%cable(cable)%L_domain(local_domain)%dim
ALLOCATE( bundle%L(domain)%mat(dim,dim) )
bundle%L(domain)%dim=dim
if (verbose) write(*,*)'Allocating bundle%L(domain) ,dim=',dim
dim=bundle%cable(cable)%C_domain(local_domain)%dim
ALLOCATE( bundle%C(domain)%mat(dim,dim) )
bundle%C(domain)%dim=dim
if (verbose) write(*,*)'Allocating bundle%C(domain) ,dim=',dim
dim=bundle%cable(cable)%Z_domain(local_domain)%dim
ALLOCATE( bundle%Z(domain)%sfilter_mat(dim,dim) )
bundle%Z(domain)%dim=dim
if (verbose) write(*,*)'Allocating bundle%Z(domain) ,dim=',dim
dim=bundle%cable(cable)%Y_domain(local_domain)%dim
ALLOCATE( bundle%Y(domain)%sfilter_mat(dim,dim) )
bundle%Y(domain)%dim=dim
if (verbose) write(*,*)'Allocating bundle%Y(domain) ,dim=',dim
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)
do row_l=1,local_n_conductors-1 ! subtract 1 as the reference conductor is included
do col_l=1,local_n_conductors-1 ! subtract 1 as the reference conductor is included
bundle%L(domain)%mat(row_l,col_l)=bundle%cable(cable)%L_domain(local_domain)%mat(row_l,col_l)
bundle%C(domain)%mat(row_l,col_l)=bundle%cable(cable)%C_domain(local_domain)%mat(row_l,col_l)
bundle%Z(domain)%sfilter_mat(row_l,col_l)=bundle%cable(cable)%Z_domain(local_domain)%sfilter_mat(row_l,col_l)
bundle%Y(domain)%sfilter_mat(row_l,col_l)=bundle%cable(cable)%Y_domain(local_domain)%sfilter_mat(row_l,col_l)
! copy the domain based L and C matrices to the global L and C in the bundle structure
! in the global L,C structure rows and columns correspond to the global_domain conductor number
row_g=terminal_conductor_to_global_domain_conductor(terminal_conductor+row_l)
col_g=terminal_conductor_to_global_domain_conductor(terminal_conductor+col_l)
bundle%global_L%mat(row_g,col_g)=bundle%L(domain)%mat(row_l,col_l)
bundle%global_C%mat(row_g,col_g)=bundle%C(domain)%mat(row_l,col_l)
bundle%global_Z%sfilter_mat(row_g,col_g)=bundle%Z(domain)%sfilter_mat(row_l,col_l)
bundle%global_Y%sfilter_mat(row_g,col_g)=bundle%Y(domain)%sfilter_mat(row_l,col_l)
end do ! next column of matrix
end do ! next row of matrix
! Added CJS 27/4/2016
bundle%terminal_conductor_list(domain)%n_elements=local_n_conductors
ALLOCATE( bundle%terminal_conductor_list(domain)%element(1:local_n_conductors) )
do conductor=1,local_n_conductors-1 ! do reference conductor separately
bundle%terminal_conductor_list(domain)%element(conductor)=terminal_conductor+conductor
end do ! next conductor in this domain
! reference conductor
reference_conductor=global_domain_reference_conductor(domain) ! note domain based numbering...
write(*,*)'Domain=',domain
write(*,*)'Global domain reference conductor=',reference_conductor
bundle%terminal_conductor_list(domain)%element(local_n_conductors)= &
global_domain_conductor_to_terminal_conductor(reference_conductor)
terminal_conductor=terminal_conductor+local_n_conductors-1 ! subtract 1 as the count includes the reference conductor
else
! This is an external domain so leave until later but count the global conductors.
local_n_conductors=bundle%cable(cable)%local_domain_n_conductors(local_domain)-1 ! subtract 1 as the reference conductor is included
do local_conductor=1,local_n_conductors
terminal_conductor=terminal_conductor+1
end do
end if ! internal or external domain
end do ! next local domain
end do ! next cable
! 7. Calculate the inductance and capacitance matrices for the external domains (domains within overshields and the external domain)
if(verbose) write(*,*)'first external domain:',first_external_domain
if(verbose) write(*,*)'total number of domains:',tot_n_domains
overshield=0 ! counter for overshield domains
do domain=first_external_domain,tot_n_viable_domains ! exclude the external domain if there is only one conductor
! allocate memory for the PUL parameter solver interface
if(verbose) write(*,*)'Domain:',domain
if(verbose) write(*,*)'Allocating PUL data structure for ',bundle%n_conductors(domain),' conductors'
CALL allocate_and_reset_PUL_data(PUL,bundle%n_conductors(domain))
! copy external conductor information to the PUL structure
conductor=0 ! this provides a count of the external domain conductor numbering for PUL parameter calculation
! loop over cables
do cable=1,bundle%n_cables
if (cable_reference_domain(cable).EQ.domain) then
! The reference domain of this cable is the domain we are currently working on so add the external
! conductor information for this cable to the PUL structure
do local_conductor=1,bundle%cable(cable)%n_external_conductors
if (bundle%cable(cable)%cable_type.NE.cable_geometry_type_ground_plane) then
conductor=conductor+1 ! add another conductor to the external domain
if(verbose) write(*,*)'Adding conductor number',local_conductor,' from cable',cable,'. Domain conductor',conductor
PUL%shape(conductor)=bundle%cable(cable)%external_model(local_conductor)%conductor_type
PUL%x(conductor)=bundle%cable_x_offset(cable)
PUL%y(conductor)=bundle%cable_y_offset(cable)
PUL%rtheta(conductor)=bundle%cable_angle(cable)
PUL%o(conductor)=bundle%cable(cable)%external_model(local_conductor)%conductor_ox
PUL%r(conductor)=bundle%cable(cable)%external_model(local_conductor)%conductor_radius
PUL%rw(conductor)=bundle%cable(cable)%external_model(local_conductor)%conductor_width
PUL%rw2(conductor)=bundle%cable(cable)%external_model(local_conductor)%conductor_width2
PUL%rh(conductor)=bundle%cable(cable)%external_model(local_conductor)%conductor_height
PUL%rd(conductor)=bundle%cable(cable)%external_model(local_conductor)%dielectric_radius
PUL%rdw(conductor)=bundle%cable(cable)%external_model(local_conductor)%dielectric_width
PUL%rdh(conductor)=bundle%cable(cable)%external_model(local_conductor)%dielectric_height
PUL%rdo(conductor)=bundle%cable(cable)%external_model(local_conductor)%dielectric_ox
PUL%epsr(conductor)=bundle%cable(cable)%external_model(local_conductor)%dielectric_epsr
end if ! not a ground plane
end do ! next cable external conductor
end if ! cable contributes to this domain
end do ! next cable
! Calculate the per-unit-length parameters (inductance and capacitance matrices)
! if this is an overshield domain then
if (verbose) write(*,*)'domain=',domain,' last domain(check)=',first_external_domain+tot_n_overshields
if(domain.LT.(first_external_domain+n_overshield_domains)) then
overshield=overshield+1
if (verbose) write(*,*)'PUL parameter calculation for oversheild domain'
! no ground plane
PUL%ground_plane_present=.FALSE.
PUL%ground_plane_angle =0d0
PUL%ground_plane_offset =0d0
! add overshield information
if (verbose) write(*,*)'Add overshield information'
is_overshield_domain=.TRUE.
PUL%overshield_present=.TRUE.
overshield=domain-first_external_domain+1
PUL%overshield_shape = overshield_shape(overshield)
PUL%overshield_x = overshield_x(overshield)
PUL%overshield_y = overshield_y(overshield)
PUL%overshield_r = overshield_r(overshield)
PUL%overshield_w = overshield_w(overshield)
PUL%overshield_w2 = overshield_w2(overshield)
PUL%overshield_h = overshield_h(overshield)
PUL%epsr_background = 1d0 ! background permittivity =1.0 within an overshield i.e. cables are in air
if (use_Laplace) then
CALL PUL_LC_Laplace(PUL,bundle%bundle_name,bundle%Y_fit_model_order,bundle%Y_fit_freq_spec,domain)
else
if (verbose) write(*,*)'CALL PUL_LC_calc_overshield_wide_separation_approximation'
CALL PUL_LC_calc_overshield_wide_separation_approximation(PUL)
end if ! use_Laplace or not...
else
! this is an external domain
! copy ground plane information
PUL%ground_plane_present=bundle%ground_plane_present
PUL%ground_plane_angle =bundle%ground_plane_angle
PUL%ground_plane_offset =bundle%ground_plane_offset
! No overshield information
is_overshield_domain=.FALSE.
PUL%overshield_present=.FALSE.
PUL%overshield_shape=0
PUL%overshield_r= 0d0
PUL%overshield_w= 0d0
PUL%overshield_w2= 0d0
PUL%overshield_h= 0d0
PUL%epsr_background = 1d0 ! background permittivity =1.0 i.e. cables are in air
if (use_Laplace) then
CALL PUL_LC_Laplace(PUL,bundle%bundle_name,bundle%Y_fit_model_order,bundle%Y_fit_freq_spec,domain)
else
CALL PUL_LC_calc_wide_separation_approximation(PUL)
end if ! use_Laplace or not...
end if ! last external domain (i.e. not an overshield domain)
! We now have the L and C matrices for this external domain
! Copy the domain based L and C matrices to the domain based L and C in the bundle structure
if (verbose) write(*,*)'domain=',domain
dim=PUL%L%dim
if (verbose) write(*,*)'Allocating bundle%L(domain) ,dim=',dim
ALLOCATE( bundle%L(domain)%mat(dim,dim) )
bundle%L(domain)%dim=dim
dim=PUL%C%dim
if (verbose) write(*,*)'Allocating bundle%C(domain) ,dim=',dim
ALLOCATE( bundle%C(domain)%mat(dim,dim) )
bundle%C(domain)%dim=dim
dim=PUL%Zfilter%dim
if (verbose) write(*,*)'Allocating bundle%Z(domain) ,dim=',dim
Bundle%Z(domain)%dim=dim
ALLOCATE(Bundle%Z(domain)%sfilter_mat(dim,dim))
dim=PUL%Yfilter%dim
if (verbose) write(*,*)'Allocating bundle%Y(domain) ,dim=',dim
Bundle%Y(domain)%dim=dim
ALLOCATE(Bundle%Y(domain)%sfilter_mat(dim,dim))
local_n_conductors=bundle%n_conductors(domain)
if (is_overshield_domain) then
if (verbose) write(*,*)'Copying L, C, Z, Y matrices in overshield domain, n_conductors=',local_n_conductors, &
overshield_n_conductors(overshield)+1
do row_l=1,local_n_conductors-1 ! Note that the reference conductor is included in the conductor count here
do col_l=1,local_n_conductors-1 ! Note that the reference conductor is included in the conductor count here
! In the global L,C structure rows and columns correspond to the global_domain conductor number
row_g=terminal_conductor_to_global_domain_conductor(overshield_terminal_conductor(overshield,row_l))
col_g=terminal_conductor_to_global_domain_conductor(overshield_terminal_conductor(overshield,col_l))
bundle%L(domain)%mat(row_l,col_l)=PUL%L%mat(row_l,col_l)
bundle%C(domain)%mat(row_l,col_l)=PUL%C%mat(row_l,col_l)
bundle%Z(domain)%sfilter_mat(row_l,col_l)=PUL%Zfilter%sfilter_mat(row_l,col_l)
bundle%Y(domain)%sfilter_mat(row_l,col_l)=PUL%Yfilter%sfilter_mat(row_l,col_l)
! copy the domain based L and C matrices to the global L and C in the bundle structure
bundle%global_L%mat(row_g,col_g)=bundle%L(domain)%mat(row_l,col_l)
bundle%global_C%mat(row_g,col_g)=bundle%C(domain)%mat(row_l,col_l)
! copy the domain based Z and Y filter matrices to the global Z and Y in the bundle structure
bundle%global_Z%sfilter_mat(row_g,col_g)=bundle%Z(domain)%sfilter_mat(row_l,col_l)
bundle%global_Y%sfilter_mat(row_g,col_g)=bundle%Y(domain)%sfilter_mat(row_l,col_l)
end do ! next column of matrix
end do ! next row of matrix
! Added CJS 27/4/2016
bundle%terminal_conductor_list(domain)%n_elements=local_n_conductors
ALLOCATE( bundle%terminal_conductor_list(domain)%element(1:local_n_conductors) )
do conductor=1,local_n_conductors-1 ! do reference conductor separately
bundle%terminal_conductor_list(domain)%element(conductor)=overshield_terminal_conductor(overshield,conductor)
end do ! next conductor in this domain
! reference conductor
reference_conductor=global_domain_reference_conductor(domain) ! note domain based numbering...
bundle%terminal_conductor_list(domain)%element(local_n_conductors)= &
global_domain_conductor_to_terminal_conductor(reference_conductor)
else
! external domain
write(*,*)'External domain, n_conductors=',local_n_conductors,' dim=',local_n_conductors-1
do row_l=1,local_n_conductors-1 ! subtract 1 as the reference conductor is included
do col_l=1,local_n_conductors-1 ! subtract 1 as the reference conductor is included
! In the global L,C structure rows and columns correspond to the bundle_domain conductor number
row_g=terminal_conductor_to_global_domain_conductor(external_terminal_conductor(row_l))
col_g=terminal_conductor_to_global_domain_conductor(external_terminal_conductor(col_l))
if (verbose) write(*,*)'Copy L,C from PUL structure'
bundle%L(domain)%mat(row_l,col_l)=PUL%L%mat(row_l,col_l)
bundle%C(domain)%mat(row_l,col_l)=PUL%C%mat(row_l,col_l)
if (verbose) write(*,*)'Copy Z,Y from PUL structure'
bundle%Z(domain)%sfilter_mat(row_l,col_l)=PUL%Zfilter%sfilter_mat(row_l,col_l)
bundle%Y(domain)%sfilter_mat(row_l,col_l)=PUL%Yfilter%sfilter_mat(row_l,col_l)
! copy the domain based L and C matrices to the global L and C in the bundle structure
if (verbose) write(*,*)'Copy L,C from bundle structure'
bundle%global_L%mat(row_g,col_g)=bundle%L(domain)%mat(row_l,col_l)
bundle%global_C%mat(row_g,col_g)=bundle%C(domain)%mat(row_l,col_l)
if (verbose) write(*,*)'Copy Z,Y from bundle structure'
! copy the domain based Z and Y filter matrices to the global Z and Y in the bundle structure
bundle%global_Z%sfilter_mat(row_g,col_g)=bundle%Z(domain)%sfilter_mat(row_l,col_l)
bundle%global_Y%sfilter_mat(row_g,col_g)=bundle%Y(domain)%sfilter_mat(row_l,col_l)
end do ! next column of matrix
end do ! next row of matrix
! Added CJS 27/4/2016
bundle%terminal_conductor_list(domain)%n_elements=local_n_conductors
ALLOCATE( bundle%terminal_conductor_list(domain)%element(1:local_n_conductors) )
do conductor=1,local_n_conductors-1 ! do reference conductor separately
bundle%terminal_conductor_list(domain)%element(conductor)=external_terminal_conductor(conductor)
end do ! next conductor in this domain
! reference conductor
reference_conductor=global_domain_reference_conductor(domain) ! note domain based numbering...
bundle%terminal_conductor_list(domain)%element(local_n_conductors)= &
global_domain_conductor_to_terminal_conductor(reference_conductor)
end if ! external domain
CALL deallocate_PUL_data(PUL)
end do ! next external domain
! 8. Copy the cable based conductor impedance (loss) models to the bundle structure
conductor=0 ! count of terminal conductors
do cable=1,tot_n_cables
do local_conductor=1,bundle%cable(cable)%tot_n_conductors
conductor=conductor+1
! copy the conductor impedance model for this cable conductor to the bundle structure
bundle%conductor_impedance(conductor)%impedance_model_type= &
bundle%cable(cable)%conductor_impedance(local_conductor)%impedance_model_type
bundle%conductor_impedance(conductor)%radius= &
bundle%cable(cable)%conductor_impedance(local_conductor)%radius
bundle%conductor_impedance(conductor)%width= &
bundle%cable(cable)%conductor_impedance(local_conductor)%width
bundle%conductor_impedance(conductor)%height= &
bundle%cable(cable)%conductor_impedance(local_conductor)%height
bundle%conductor_impedance(conductor)%conductivity= &
bundle%cable(cable)%conductor_impedance(local_conductor)%conductivity
bundle%conductor_impedance(conductor)%thickness= &
bundle%cable(cable)%conductor_impedance(local_conductor)%thickness
bundle%conductor_impedance(conductor)%Resistance_multiplication_factor= &
bundle%cable(cable)%conductor_impedance(local_conductor)%Resistance_multiplication_factor
if((bundle%conductor_impedance(conductor)%impedance_model_type.EQ.impedance_model_type_filter).OR. &
(bundle%conductor_impedance(conductor)%impedance_model_type.EQ.impedance_model_type_cylindrical_shield)) then
bundle%conductor_impedance(conductor)%ZT_filter= &
bundle%cable(cable)%conductor_impedance(local_conductor)%ZT_filter
end if
end do ! next conductor on this cable
end do ! next cable
! 8b. Copy the cable based conductor labels to the bundle structure
ALLOCATE( bundle%conductor_label(1:bundle%tot_n_conductors) )
conductor=0 ! count of terminal conductors
do cable=1,tot_n_cables
do local_conductor=1,bundle%cable(cable)%tot_n_conductors
conductor=conductor+1
! copy the conductor impedance model for this cable conductor to the bundle structure
write(conductor_string,'(I3)')conductor
bundle%conductor_label(conductor)='Conductor number '//conductor_string//'. '// &
trim(bundle%cable(cable)%conductor_label(local_conductor))
end do ! next conductor on this cable
end do ! next cable
! 9 save numbering information required for the transfer impedance calculation
! first loop over shielded domains. The reference conductor for each domain is a shield (by definition)
! apart from the shielded twisted pair differential mode exception
! so record this hence set out the inner domain number for shields
do domain=1,bundle%tot_n_domains-1 ! note we exclude the exterior domain here
reference_conductor=global_domain_reference_conductor(domain)
terminal_conductor=global_domain_conductor_to_terminal_conductor(reference_conductor)
if (.NOT.domain_is_TP_differential_mode(domain)) then
bundle%terminal_conductor_is_shield_flag(terminal_conductor)=.TRUE.
bundle%terminal_conductor_to_inner_domain(terminal_conductor)=domain
end if
end do ! next conductor
! work out the outer domain for each conductor and the associated reference conductor
do conductor=1,bundle%tot_n_conductors
bundle%terminal_conductor_to_outer_domain(conductor)=terminal_conductor_to_global_domain(conductor)
bundle%terminal_conductor_to_global_domain_conductor(conductor)=terminal_conductor_to_global_domain_conductor(conductor)
bundle%terminal_conductor_to_reference_terminal_conductor(conductor)= &
terminal_conductor_to_reference_terminal_conductor(conductor)
end do ! next conductor
! 10. finish up
if (allocated( overshield_shape )) DEALLOCATE( overshield_shape)
if (allocated( overshield_x )) DEALLOCATE( overshield_x)
if (allocated( overshield_y )) DEALLOCATE( overshield_y)
if (allocated( overshield_r )) DEALLOCATE( overshield_r)
if (allocated( overshield_w )) DEALLOCATE( overshield_w)
if (allocated( overshield_w2 )) DEALLOCATE( overshield_w2)
if (allocated( overshield_h )) DEALLOCATE( overshield_h)
if (allocated( overshield_domain )) DEALLOCATE( overshield_domain)
if (allocated( overshield_reference_terminal_conductor)) DEALLOCATE( overshield_reference_terminal_conductor )
if (allocated( global_domain_reference_conductor )) DEALLOCATE( global_domain_reference_conductor )
DEALLOCATE( cable_reference_conductor )
DEALLOCATE( cable_reference_domain )
! Deallocate the referencing arrays
DEALLOCATE( terminal_conductor_to_cable )
DEALLOCATE( terminal_conductor_to_cable_local_domain )
DEALLOCATE( terminal_conductor_to_global_domain )
DEALLOCATE( terminal_conductor_to_global_domain_conductor )
DEALLOCATE( terminal_conductor_to_reference_global_domain_conductor )
DEALLOCATE( terminal_conductor_to_reference_terminal_conductor )
DEALLOCATE( terminal_conductor_is_reference_conductor )
DEALLOCATE( global_domain_conductor_to_terminal_conductor )
DEALLOCATE( external_terminal_conductor )
if (allocated( domain_is_TP_differential_mode )) DEALLOCATE( domain_is_TP_differential_mode )
END SUBROUTINE create_global_domain_structure