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|
*DECK MCGPTF
SUBROUTINE MCGPTF(SUBFFI,SUBFFA,SUBSCH,IFTRAK,N2BTR,N2MAX,
1 KPN,K,NREG,M,NGEFF,NANGL,NMU,NANI,NFUNL,NMOD,
2 KEYFLX,KEYCUR,NZON,NCONV,CAZ1,CAZ2,XMU,WZMU,PHI,
3 S,SIGAL,ISGNR,NMAX,NZP,N2REG,N2SOU,DELU,INDREG,
4 Z,VNORF,CMU,CMUI,SMU,SMUI,TMU,TMUI,SSYM,IDIR)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Flux integration upon the tracking (3D prismatic extended tracking).
*
*Copyright:
* Copyright (C) 2002 Ecole Polytechnique de Montreal
* This library is free software; you can redistribute it and/or
* modify it under the terms of the GNU Lesser General Public
* License as published by the Free Software Foundation; either
* version 2.1 of the License, or (at your option) any later version
*
*Author(s): R. Le Tellier
*
*Parameters: input
* SUBFFI isotropic flux integration subroutine.
* SUBFFA anisotropic flux integration subroutine.
* SUBSCH track coefficients calculation subroutine.
* IFTRAK tracking file unit number.
* N2BTR total number of 2D tracking lines.
* N2MAX maximum number of elements in a 2D track.
* KPN total number of unknowns in vectors PHI.
* K total number of volumes for which specific values
* of the neutron flux and reactions rates are required.
* NREG number of volumes.
* M number of material mixtures.
* NGEFF number of groups to process.
* NANGL number of tracking angles in the tracking file.
* NMU order of the polar quadrature in 2D / 1 in 3D.
* NANI scattering anisotropy (=1 for isotropic scattering).
* NFUNL number of moments of the flux (in 2D: NFUNL=NANI*(NANI+1)/2).
* NMOD first dimension of ISGNR.
* KEYFLX position of flux elements in PHI vector.
* KEYCUR position of current elements in PHI vector.
* NZON index-number of the mixture type assigned to each volume.
* NCONV logical array of convergence status for each group (.TRUE.
* not converged).
* CAZ1 first cosines of the different tracking azimuthal angles.
* CAZ2 second cosines of the different tracking azimuthal angles.
* XMU cosines of the different tracking polar angles.
* (polar quadrature in 2D / tracking angles in 3D).
* WZMU polar quadrature set in 2D.
* S total source vector components.
* SIGAL total cross-section and albedo array.
* ISGNR spherical harmonic signs.
* NMAX maximum number of segments for the 3D tracks.
* NZP number of z-plans.
* N2SOU number of external surfaces in the 2D tracking.
* N2REG number of regions in the 2D tracking.
* DELU input track spacing for 3D track reconstruction.
* INDREG region/surface index to go from the 2D to the 3D geometry.
* Z z-plan coordinates.
* VNORF normalization factors per angle.
* CMU polar angle cosines.
* CMUI inverse of polar angle cosines.
* SMU polar angle sines.
* SMUI inverse of polar angle sines.
* TMU polar angle tangents.
* TMUI inverse of polar angle tangents.
* SSYM symmetry flag.
* IDIR direction of fundamental current for TIBERE with MoC
* (=0,1,2,3).
*
*Parameters: input/output
* PHI vector containing the zonal scalar flux.
*
*-----------------------------------------------------------------------
*
IMPLICIT NONE
*----
* SUBROUTINE ARGUMENTS
*----
INTEGER NGEFF,K,KPN,M,N2MAX,NMU,NZON(K),NANI,NFUNL,NMOD,
1 NREG,KEYFLX(NREG,NFUNL),KEYCUR(K-NREG),IFTRAK,N2BTR,NANGL,
2 ISGNR(NMOD,NFUNL),NMAX,NZP,N2REG,N2SOU,
3 INDREG(-N2SOU:N2REG,0:NZP+1),SSYM,IDIR
REAL WZMU(NMU),SIGAL(-6:M,NGEFF),XMU(NMU),DELU,Z(0:NZP)
DOUBLE PRECISION CAZ1(NANGL),CAZ2(NANGL),PHI(KPN,NGEFF),
1 S(KPN,NGEFF),VNORF(NREG,NANGL,NMU,2),CMU(NMU),CMUI(NMU),
2 SMU(NMU),SMUI(NMU),TMU(NMU),TMUI(NMU)
LOGICAL NCONV(NGEFF)
EXTERNAL SUBFFI,SUBFFA,SUBSCH
*----
* LOCAL VARIABLES
*----
INTEGER MODUR,MODDL,MODDR,MODUL
PARAMETER(MODUR=1,MODDL=8,MODDR=5,MODUL=4)
INTEGER II,I2LIN,IANG,N2SEG,NR2D,NBTR,KST,IST,ILINE,N3D,I,I1,I2,
1 IMU,IANG0,NOMP,INDP,NOMM,INDM,NOMI,JF,IND,TIN,N3DP,NSUB
DOUBLE PRECISION W2D,Q0,Q1,CPO,CPOI,SPO,SPOI,TPO,TPOI,LTOT,DELTE,
1 DELZE,T,Z1,Z2,TP,Z1P,W3DPO,WPO,W3D,OMEGAX,OMEGAY,OMEGAZ
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: NOM2D,NOM3D
REAL, ALLOCATABLE, DIMENSION(:,:) :: RHARM
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: TRHAR
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:) :: H2D,H3D,T2D,B
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:,:,:) :: STOT
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(NOM2D(N2MAX),H2D(N2MAX),NOM3D(NMAX),H3D(NMAX),B(4*NMAX),
1 T2D(0:N2MAX-1))
*
IF(NANI.EQ.1) THEN
*---
* ISOTROPIC SCATTERING
*---
DO I2LIN=1,N2BTR
READ(IFTRAK) NSUB,N2SEG,W2D,IANG,(NOM2D(I),I=1,N2SEG),
1 (H2D(I),I=1,N2SEG)
IF(NSUB.NE.1) CALL XABORT('MCGPTF: NSUB.NE.1.')
NR2D=N2SEG-2
T2D(0)=0.0
DO II=1,NR2D
T2D(II)=T2D(II-1)+H2D(II+1)
ENDDO
DO IMU=1,NMU
CPO=CMU(IMU)
CPOI=CMUI(IMU)
SPO=SMU(IMU)
SPOI=SMUI(IMU)
TPO=TMU(IMU)
TPOI=TMUI(IMU)
WPO=WZMU(IMU)
IF(SSYM.EQ.2) GOTO 15
*---
* CONSTRUCT THE 3D TRACKS WHICH ENTER THE GEOMETRY THROUGH A BOTTOM/TOP
* SURFACE
*---
* length of the spatial integration interval
LTOT=T2D(NR2D)*CPO
* number of 3D tracks generated for this x-y track and this polar
* direction
NBTR=INT(LTOT/DELU)+1
* effective track spacing in T
DELTE=T2D(NR2D)/DBLE(NBTR)
W3DPO=W2D*DELTE*CPO
W3D=WPO*W3DPO
T=-0.5D0*DELTE
KST=1
DO 10 ILINE=1,NBTR
T=T+DELTE
TP=T
DO WHILE (T2D(KST).LT.T)
KST=KST+1
ENDDO
K=KST
* ---
* positive polar sine track
* ---
I1=1
Z1=Z(I1-1)
TIN=0
N3D=1
NOM3D(N3D)=INDREG(NOM2D(K+1),0)
H3D(N3D)=0.5D0
CALL MCGPT1(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I1,K,Z1,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=2,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,1)
ENDDO
IF(SSYM.EQ.1) THEN
* the top boundary condition is a surface symmetry
IF(TIN.EQ.0) THEN
* this track has encountered the top boundary -> it is reflected
N3DP=N3D
N3D=N3D-1
I1=I1-1
CALL MCGPT2(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I1,K,
1 Z1,T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=N3DP,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,2)
ENDDO
ENDIF
ENDIF
DO II=1,NGEFF
IF(NCONV(II)) THEN
* MCGFFIR: 'Source Term Isolation' Strategy turned on
* MCGFFIS: 'Source Term Isolation' Strategy turned off
* MCGFFIT: 'MOCC/MCI' Iterative Strategy
OMEGAX=0.0D0
OMEGAY=0.0D0
OMEGAZ=0.0D0
IDIR=0
CALL SUBFFI(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),S(1,II),NREG,KEYFLX,KEYCUR,PHI(1,II),
2 B,W3D,OMEGAX,OMEGAY,OMEGAZ,IDIR)
ENDIF
ENDDO
T=TP
IF(SSYM.EQ.1) GOTO 10
K=KST
* ---
* negative polar sine track
* ---
I2=NZP
Z2=Z(I2)
TIN=0
N3D=1
NOM3D(N3D)=INDREG(NOM2D(K+1),NZP+1)
H3D(N3D)=0.5D0
CALL MCGPT2(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I2,K,Z2,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=2,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,2)
ENDDO
DO II=1,NGEFF
IF(NCONV(II)) THEN
* MCGFFIR: 'Source Term Isolation' Strategy turned on
* MCGFFIS: 'Source Term Isolation' Strategy turned off
* MCGFFIT: 'MOCC/MCI' Iterative Strategy
OMEGAX=0.0D0
OMEGAY=0.0D0
OMEGAZ=0.0D0
IDIR=0
CALL SUBFFI(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),S(1,II),NREG,KEYFLX,KEYCUR,PHI(1,II),
2 B,W3D,OMEGAX,OMEGAY,OMEGAZ,IDIR)
ENDIF
ENDDO
* ---
T=TP
10 CONTINUE
*---
* CONSTRUCT THE 3D TRACKS WHICH ENTER THE GEOMETRY THROUGH A LATERAL
* SURFACE
*---
* length of the spatial integration interval
15 LTOT=Z(NZP)*SPO
! LTOT=(Z(NZP)-Z(0))*SPO with Z(0)=0.0
* number of 3D tracks generated for this x-y track and this polar
* direction
NBTR=INT(LTOT/DELU)+1
* effective track spacing in Z
DELZE=Z(NZP)/DBLE(NBTR)
! DELZE=(Z(NZP)-Z(0))/DBLE(NBTR) with Z(0)=0.0
W3DPO=W2D*DELZE*SPO
W3D=WPO*W3DPO
Z1=-0.5D0*DELZE
! Z1=Z(0)-0.5D0*DELZE with Z(0)=0.0
IST=1
DO 20 ILINE=1,NBTR
Z1=Z1+DELZE
Z1P=Z1
DO WHILE (Z(IST).LT.Z1)
IST=IST+1
ENDDO
I=IST
* ---
* positive polar sine track
* ---
K=1
T=T2D(K-1)
TIN=1
N3D=1
N3DP=2
NOM3D(N3D)=INDREG(NOM2D(1),IST)
H3D(N3D)=0.5D0
21 CONTINUE
CALL MCGPT1(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I,K,Z1,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=N3DP,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,1)
ENDDO
IF(SSYM.GT.0) THEN
* the top boundary condition is a surface symmetry
IF(TIN.EQ.0) THEN
* this track has encountered the top boundary -> it is reflected
N3DP=N3D
N3D=N3D-1
I=I-1
CALL MCGPT2(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I,K,
1 Z1,T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=N3DP,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,2)
ENDDO
IF((SSYM.EQ.2).AND.(TIN.EQ.0)) THEN
* the bottom boundary is a surface symmetry
* this track has encountered the bottom boundary -> it is
* reflected
N3DP=N3D
N3D=N3D-1
I=I+1
GOTO 21
ENDIF
ENDIF
ENDIF
DO II=1,NGEFF
IF(NCONV(II)) THEN
* MCGFFIR: 'Source Term Isolation' Strategy turned on
* MCGFFIS: 'Source Term Isolation' Strategy turned off
* MCGFFIT: 'MOCC/MCI' Iterative Strategy
OMEGAX=0.0D0
OMEGAY=0.0D0
OMEGAZ=0.0D0
IDIR=0
CALL SUBFFI(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),S(1,II),NREG,KEYFLX,KEYCUR,PHI(1,II),
2 B,W3D,OMEGAX,OMEGAY,OMEGAZ,IDIR)
ENDIF
ENDDO
Z1=Z1P
I=IST
* ---
* negative polar sine track
* ---
K=1
T=T2D(K-1)
TIN=1
N3D=1
N3DP=2
NOM3D(N3D)=INDREG(NOM2D(1),IST)
H3D(N3D)=0.5D0
22 CONTINUE
CALL MCGPT2(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I,K,Z1,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=N3DP,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,2)
ENDDO
IF(SSYM.EQ.2) THEN
* the bottom boundary is a surface symmetry
IF(TIN.EQ.0) THEN
* this track has encountered the bottom boundary -> it is
* reflected
N3DP=N3D
N3D=N3D-1
I=I+1
CALL MCGPT1(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I,K,
1 Z1,T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=N3DP,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,1)
ENDDO
IF(TIN.EQ.0) THEN
* the top boundary is a surface symmetry
* this track has encountered the top boundary -> it is
* reflected
N3DP=N3D
N3D=N3D-1
I=I-1
GOTO 22
ENDIF
ENDIF
ENDIF
DO II=1,NGEFF
IF(NCONV(II)) THEN
* MCGFFIR: 'Source Term Isolation' Strategy turned on
* MCGFFIS: 'Source Term Isolation' Strategy turned off
* MCGFFIT: 'MOCC/MCI' Iterative Strategy
OMEGAX=0.0D0
OMEGAY=0.0D0
OMEGAZ=0.0D0
IDIR=0
CALL SUBFFI(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),S(1,II),NREG,KEYFLX,KEYCUR,PHI(1,II),
2 B,W3D,OMEGAX,OMEGAY,OMEGAZ,IDIR)
ENDIF
ENDDO
* ---
Z1=Z1P
20 CONTINUE
ENDDO
ENDDO
ELSE
*---
* ANISOTROPIC SCATTERING
*---
ALLOCATE(STOT(NMAX,NMU,NGEFF,2))
STOT(:NMAX,:NMU,:NGEFF,:2)=0.0D0
ALLOCATE(RHARM(NMU,NFUNL),TRHAR(NMU,NFUNL,4))
IANG0=0
DO I2LIN=1,N2BTR
READ(IFTRAK) NSUB,N2SEG,W2D,IANG,(NOM2D(I),I=1,N2SEG),
1 (H2D(I),I=1,N2SEG)
IF(NSUB.NE.1) CALL XABORT('MCGPTF: NSUB.NE.1.')
NR2D=N2SEG-2
T2D(0)=0.0
DO II=1,NR2D
T2D(II)=T2D(II-1)+H2D(II+1)
ENDDO
IF(IANG.NE.IANG0) THEN
IANG0=IANG
CALL MOCCHR(3,NANI-1,NFUNL,NMU,XMU,CAZ1(IANG),CAZ2(IANG),
1 RHARM)
DO 26 JF=1,NFUNL
DO 25 IMU=1,NMU
! positive polar sine track
TRHAR(IMU,JF,1)=ISGNR(MODUR,JF)*RHARM(IMU,JF)
TRHAR(IMU,JF,2)=ISGNR(MODDL,JF)*RHARM(IMU,JF)
! negative polar sine track
TRHAR(IMU,JF,3)=ISGNR(MODDR,JF)*RHARM(IMU,JF)
TRHAR(IMU,JF,4)=ISGNR(MODUL,JF)*RHARM(IMU,JF)
25 CONTINUE
26 CONTINUE
ENDIF
DO IMU=1,NMU
CPO=CMU(IMU)
CPOI=CMUI(IMU)
SPO=SMU(IMU)
SPOI=SMUI(IMU)
TPO=TMU(IMU)
TPOI=TMUI(IMU)
WPO=WZMU(IMU)
*---
* CONSTRUCT THE 3D TRACKS WHICH ENTER THE GEOMETRY THROUGH A BOTTOM/TOP
* SURFACE
*---
* length of the spatial integration interval
LTOT=T2D(NR2D)*CPO
* number of 3D tracks generated for this x-y track and this polar
* direction
NBTR=INT(LTOT/DELU)+1
* effective track spacing in T
DELTE=T2D(NR2D)/DBLE(NBTR)
W3DPO=W2D*DELTE*CPO
W3D=WPO*W3DPO
T=-0.5D0*DELTE
KST=1
DO 30 ILINE=1,NBTR
T=T+DELTE
TP=T
DO WHILE (T2D(KST).LT.T)
KST=KST+1
ENDDO
K=KST
* ---
* positive polar sine track
* ---
I1=1
Z1=Z(I1-1)
TIN=0
N3D=1
NOM3D(N3D)=INDREG(NOM2D(K+1),0)
H3D(N3D)=0.5D0
CALL MCGPT1(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I1,K,Z1,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=2,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,1)
ENDDO
DO II=1,NGEFF
IF(NCONV(II)) THEN
* incoming flux in + direction
NOMP=NOM3D(1)
INDP=KEYCUR(-NOMP)
* incoming flux in - direction
NOMM=NOM3D(N3D)
INDM=KEYCUR(-NOMM)
STOT(1,IMU,II,1)=W3D*S(INDP,II)
STOT(N3D,IMU,II,2)=W3D*S(INDM,II)
* regional sources
DO I=2,N3D-1
NOMI=NOM3D(I)
Q0=0.0D0
Q1=0.0D0
DO JF=1,NFUNL
IND=KEYFLX(NOMI,JF)
Q0=Q0+S(IND,II)*TRHAR(IMU,JF,1)
Q1=Q1+S(IND,II)*TRHAR(IMU,JF,2)
ENDDO
STOT(I,IMU,II,1)=W3D*Q0
STOT(I,IMU,II,2)=W3D*Q1
ENDDO
* MCGFFAR: 'Source Term Isolation' Strategy turned on
* MCGFFAS: 'Source Term Isolation' Strategy turned off
* MCGFFAT: 'MOCC/MCI' Iterative Strategy
CALL SUBFFA(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),STOT(1,IMU,II,1),STOT(1,IMU,II,2),
2 NREG,NMU,NANI,NFUNL,TRHAR(1,1,1),KEYFLX,KEYCUR,
3 IMU,PHI(1,II),B)
ENDIF
ENDDO
T=TP
K=KST
* ---
* negative polar sine track
* ---
I2=NZP
Z2=Z(I2)
TIN=0
N3D=1
NOM3D(N3D)=INDREG(NOM2D(K+1),NZP+1)
H3D(N3D)=0.5D0
CALL MCGPT2(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I2,K,Z2,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=2,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,2)
ENDDO
DO II=1,NGEFF
IF(NCONV(II)) THEN
* incoming flux in + direction
NOMP=NOM3D(1)
INDP=KEYCUR(-NOMP)
* incoming flux in - direction
NOMM=NOM3D(N3D)
INDM=KEYCUR(-NOMM)
STOT(1,IMU,II,1)=W3D*S(INDP,II)
STOT(N3D,IMU,II,2)=W3D*S(INDM,II)
* regional sources
DO I=2,N3D-1
NOMI=NOM3D(I)
Q0=0.0D0
Q1=0.0D0
DO JF=1,NFUNL
IND=KEYFLX(NOMI,JF)
Q0=Q0+S(IND,II)*TRHAR(IMU,JF,3)
Q1=Q1+S(IND,II)*TRHAR(IMU,JF,4)
ENDDO
STOT(I,IMU,II,1)=W3D*Q0
STOT(I,IMU,II,2)=W3D*Q1
ENDDO
* MCGFFAR: 'Source Term Isolation' Strategy turned on
* MCGFFAS: 'Source Term Isolation' Strategy turned off
* MCGFFAT: 'MOCC/MCI' Iterative Strategy
CALL SUBFFA(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),STOT(1,IMU,II,1),STOT(1,IMU,II,2),
2 NREG,NMU,NANI,NFUNL,TRHAR(1,1,3),KEYFLX,KEYCUR,
3 IMU,PHI(1,II),B)
ENDIF
ENDDO
* ---
T=TP
30 CONTINUE
*---
* CONSTRUCT THE 3D TRACKS WHICH ENTER THE GEOMETRY THROUGH A LATERAL
* SURFACE
*---
* length of the spatial integration interval
LTOT=Z(NZP)*SPO
! LTOT=(Z(NZP)-Z(0))*SPO with Z(0)=0.0
* number of 3D tracks generated for this x-y track and this polar
* direction
NBTR=INT(LTOT/DELU)+1
* effective track spacing in Z
DELZE=Z(NZP)/DBLE(NBTR)
! DELZE=(Z(NZP)-Z(0))/DBLE(NBTR) with Z(0)=0.0
W3DPO=W2D*DELZE*SPO
W3D=WPO*W3DPO
Z1=-0.5D0*DELZE
! Z1=Z(0)-0.5D0*DELZE with Z(0)=0.0
IST=1
DO 40 ILINE=1,NBTR
Z1=Z1+DELZE
Z1P=Z1
DO WHILE (Z(IST).LT.Z1)
IST=IST+1
ENDDO
I=IST
* ---
* positive polar sine track
* ---
K=1
T=T2D(K-1)
TIN=1
N3D=1
NOM3D(N3D)=INDREG(NOM2D(1),IST)
H3D(N3D)=0.5D0
CALL MCGPT1(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I,K,Z1,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=2,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,1)
ENDDO
DO II=1,NGEFF
IF(NCONV(II)) THEN
* incoming flux in + direction
NOMP=NOM3D(1)
INDP=KEYCUR(-NOMP)
* incoming flux in - direction
NOMM=NOM3D(N3D)
INDM=KEYCUR(-NOMM)
STOT(1,IMU,II,1)=W3D*S(INDP,II)
STOT(N3D,IMU,II,2)=W3D*S(INDM,II)
* regional sources
DO I=2,N3D-1
NOMI=NOM3D(I)
Q0=0.0D0
Q1=0.0D0
DO JF=1,NFUNL
IND=KEYFLX(NOMI,JF)
Q0=Q0+S(IND,II)*TRHAR(IMU,JF,1)
Q1=Q1+S(IND,II)*TRHAR(IMU,JF,2)
ENDDO
STOT(I,IMU,II,1)=W3D*Q0
STOT(I,IMU,II,2)=W3D*Q1
ENDDO
* MCGFFAR: 'Source Term Isolation' Strategy turned on
* MCGFFAS: 'Source Term Isolation' Strategy turned off
* MCGFFAT: 'MOCC/MCI' Iterative Strategy
CALL SUBFFA(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),STOT(1,IMU,II,1),STOT(1,IMU,II,2),
2 NREG,NMU,NANI,NFUNL,TRHAR(1,1,1),KEYFLX,KEYCUR,
3 IMU,PHI(1,II),B)
ENDIF
ENDDO
Z1=Z1P
I=IST
* ---
* negative polar sine track
* ---
K=1
T=T2D(K-1)
TIN=1
N3D=1
NOM3D(N3D)=INDREG(NOM2D(1),IST)
H3D(N3D)=0.5D0
CALL MCGPT2(N2SOU,N2REG,NZP,NR2D,INDREG,Z,NOM2D,T2D,I,K,Z1,
1 T,TIN,CPOI,SPOI,TPO,TPOI,N3D,NOM3D,H3D)
DO II=2,N3D-1
H3D(II)=H3D(II)*VNORF(NOM3D(II),IANG,IMU,2)
ENDDO
DO II=1,NGEFF
IF(NCONV(II)) THEN
* incoming flux in + direction
NOMP=NOM3D(1)
INDP=KEYCUR(-NOMP)
* incoming flux in - direction
NOMM=NOM3D(N3D)
INDM=KEYCUR(-NOMM)
STOT(1,IMU,II,1)=W3D*S(INDP,II)
STOT(N3D,IMU,II,2)=W3D*S(INDM,II)
* regional sources
DO I=2,N3D-1
NOMI=NOM3D(I)
Q0=0.0D0
Q1=0.0D0
DO JF=1,NFUNL
IND=KEYFLX(NOMI,JF)
Q0=Q0+S(IND,II)*TRHAR(IMU,JF,3)
Q1=Q1+S(IND,II)*TRHAR(IMU,JF,4)
ENDDO
STOT(I,IMU,II,1)=W3D*Q0
STOT(I,IMU,II,2)=W3D*Q1
ENDDO
* MCGFFAR: 'Source Term Isolation' Strategy turned on
* MCGFFAS: 'Source Term Isolation' Strategy turned off
* MCGFFAT: 'MOCC/MCI' Iterative Strategy
CALL SUBFFA(SUBSCH,K,KPN,M,N3D,H3D,NOM3D,NZON,
1 SIGAL(0,II),STOT(1,IMU,II,1),STOT(1,IMU,II,2),
2 NREG,NMU,NANI,NFUNL,TRHAR(1,1,3),KEYFLX,KEYCUR,
3 IMU,PHI(1,II),B)
ENDIF
ENDDO
* ---
Z1=Z1P
40 CONTINUE
ENDDO
ENDDO
DEALLOCATE(TRHAR,RHARM,STOT)
ENDIF
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(B,H3D,NOM3D,H2D,NOM2D,T2D)
*
RETURN
END
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