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|
*DECK USSIT1
SUBROUTINE USSIT1(MAXNOR,NGRP,MASKG,IRES,IPLI0,IPTRK,IFTRAK,
1 CDOOR,IMPX,NBMIX,NREG,NUN,NL,IPHASE,MAXST,MAT,VOL,KEYFLX,LEAKSW,
2 IREX,SIGGAR,TITR,NIRES,NBNRS,NOR,CONR,GOLD,IPPT1,IPPT2,STGAR,
3 SSGAR,VOLMER,UNGAR)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Compute the multiband fluxes as required by the subgroup method using
* an iterative approach:
* a) assume a single resonant isotope;
* b) use the standard solution doors of Dragon.
*
*Copyright:
* Copyright (C) 2003 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): A. Hebert
*
*Parameters: input
* MAXNOR maximum order of the probability tables (PT).
* NGRP number of energy group.
* MASKG energy group mask pointing on self-shielded groups.
* IRES index of the resonant isotope.
* IPLI0 pointer to the internal microscopic cross section library
* builded by the self-shielding module.
* IPTRK pointer to the tracking (L_TRACK signature).
* IFTRAK file unit number used to store the tracks.
* CDOOR name of the geometry/solution operator.
* IMPX print flag (equal to zero for no print).
* NBMIX number of mixtures in the internal library.
* NREG number of regions.
* NUN number of unknowns in the flux or source vector in one
* energy group and one band.
* NL number of Legendre orders required in the calculation
* (NL=1 or higher).
* IPHASE type of flux solution (=1 use a native flux solution door;
* =2 use collision probabilities).
* MAXST maximum number of fixed point iterations for the ST scattering
* source.
* MAT index-number of the mixture type assigned to each volume.
* VOL volumes.
* KEYFLX pointers of fluxes in unknown vector.
* LEAKSW leakage switch (LEAKSW=.TRUE. if neutron leakage through
* external boundary is present).
* IREX fuel region index assigned to each mixture. Equal to zero
* in non-resonant mixtures or in mixtures not used.
* SIGGAR macroscopic x-s of the non-resonant isotopes in each mixture.
* (*,*,*,1) total; (*,*,*,2) transport correction;
* (*,*,*,3) P0 scattering; (*,*,*,4) flux times P0 scattering.
* TITR title.
* NIRES exact number of correlated resonant isotopes.
* NBNRS number of correlated fuel regions.
* NOR exact order of the probability table.
* CONR number density of the resonant isotopes.
* GOLD Goldstein-Cohen parameter (.ge.0.0).
* IPPT1 pointer to LCM directory of each resonant isotope.
* IPPT2 information related to each resonant isotope:
* IPPT2(:,1) index of a resonant region (used with infinite
* dilution case);
* IPPT2(:,2:4) alias name of resonant isotope.
* STGAR averaged microscopic total xs in resonant region.
* SSGAR averaged microscopic scattering xs in resonant region.
* VOLMER volumes of the resonant regions.
*
*Parameters: output
* UNGAR averaged flux unknowns.
*
*-----------------------------------------------------------------------
*
USE GANLIB
USE DOORS_MOD
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPLI0,IPTRK,IPPT1(NIRES)
INTEGER MAXNOR,NGRP,IRES,IFTRAK,IMPX,NBMIX,NREG,NUN,NL,
1 IPHASE,MAXST,MAT(NREG),KEYFLX(NREG),IREX(NBMIX),NIRES,NBNRS,
2 NOR(NIRES,NGRP),IPPT2(NIRES,4)
REAL VOL(NREG),SIGGAR(NBMIX,0:NIRES,NGRP,4),
1 CONR(NBNRS,NIRES),GOLD(NIRES,NGRP),STGAR(NBNRS,NIRES,NGRP),
2 SSGAR(NBNRS,NIRES,NL,NGRP),VOLMER(0:NBNRS),
3 UNGAR(NUN,NIRES,NGRP)
CHARACTER CDOOR*12,TITR*72
LOGICAL LEAKSW,MASKG(NGRP)
*----
* LOCAL VARIABLES
*----
TYPE(C_PTR) JPLIB,KPLIB,JPLI0,KPSYS,IPSYS,IPMACR,IPSOU
CHARACTER CBDPNM*12,TEXT12*12,TEXX12*12,HSMG*131
LOGICAL EMPTY,LCM,LEXAC,REBFLG
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: NPSYS
REAL, ALLOCATABLE, DIMENSION(:) :: SIGTXS,SIGS0X,SIGG,FLNEW,FUN,
1 SUN
REAL, ALLOCATABLE, DIMENSION(:,:) :: WEIGH,TOTPT,SIGWS
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: XFLUX
TYPE(C_PTR) SIGP_PTR
REAL, POINTER, DIMENSION(:) :: SIGP
*----
* FIND THE NUMBER OF COMPONENTS REQUIRED AND ALLOCATE THE LIST OF
* ASSEMBLY MATRICES.
*----
NASM=0
DO 10 IGRP=1,NGRP
IF(MASKG(IGRP).AND.(GOLD(IRES,IGRP).GT.-900.)) THEN
NASM=NASM+NOR(IRES,IGRP)
ENDIF
10 CONTINUE
IF(NASM.EQ.0) RETURN
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(NPSYS(MAXNOR*NGRP))
ALLOCATE(XFLUX(NBNRS,MAXNOR,NIRES),SIGTXS(0:NBMIX),
1 SIGS0X(0:NBMIX),SIGG(0:NBMIX),WEIGH(MAXNOR,NIRES),
2 TOTPT(MAXNOR,NIRES),SIGWS(MAXNOR,NIRES),FLNEW(NBNRS))
*----
* CREATE A SPECIFIC DIRECTORY FOR IRES-TH RESONANT ISOTOPE.
*----
WRITE(CBDPNM,'(3HCOR,I4.4,1H/,I4.4)') IRES,NIRES
CALL LCMSIX(IPLI0,CBDPNM,1)
JPLI0=LCMGID(IPLI0,'NWT0-PT')
CALL LCMLEN(IPLI0,'ASSEMB-PHYS',ILONG,ITYLCM)
IPSYS=LCMLID(IPLI0,'ASSEMB-PHYS',MAX(ILONG,NASM))
CALL LCMSIX(IPLI0,' ',2)
*----
* LOOP OVER THE ENERGY GROUPS.
*----
IASM=0
DO 100 IGRP=1,NGRP
IF(MASKG(IGRP).AND.(GOLD(IRES,IGRP).GT.-900.)) THEN
IF(IMPX.GT.2) THEN
WRITE(TEXT12,'(3A4)') (IPPT2(IRES,J0),J0=2,4)
WRITE(6,'(36H USSIT1: PROCESS CORRELATED ISOTOPE ,A12,
1 11H WITH INDEX,I3,9H IN GROUP,I4,20H (ITERATIVE METHOD).)')
2 TEXT12,IRES,IGRP
ENDIF
DO 20 JRES=1,NIRES
IF(GOLD(JRES,IGRP).EQ.-998.) THEN
WRITE(HSMG,'(28HUSSIT1: PT SET FOR ISOTOPE '',3A4,
1 10H'' IN GROUP,I4,1H.)') (IPPT2(JRES,J0),J0=2,4),IGRP
CALL XABORT(HSMG)
ELSE IF(GOLD(JRES,IGRP).EQ.-999.) THEN
WRITE(HSMG,'(30HUSSIT1: PTSL SET FOR ISOTOPE '',3A4,
1 10H'' IN GROUP,I4,1H.)') (IPPT2(JRES,J0),J0=2,4),IGRP
CALL XABORT(HSMG)
ELSE IF(GOLD(JRES,IGRP).EQ.-1000.) THEN
WRITE(HSMG,'(30HUSSIT1: PTMC SET FOR ISOTOPE '',3A4,
1 10H'' IN GROUP,I4,1H.)') (IPPT2(JRES,J0),J0=2,4),IGRP
CALL XABORT(HSMG)
ELSE IF(NOR(JRES,IGRP).GT.MAXNOR) THEN
CALL XABORT('USSIT1: MAXNOR OVERFLOW.')
ENDIF
20 CONTINUE
NORI=NOR(IRES,IGRP)
*----
* COLLECT THE BASE POINTS IN TOTAL AND PARTIAL CROSS SECTION.
*----
DO 40 JRES=1,NIRES
JPLIB=LCMGID(IPPT1(JRES),'GROUP-PT')
CALL LCMLEL(JPLIB,IGRP,ILONG,ITYLCM)
IF(ILONG.NE.0) THEN
KPLIB=LCMGIL(JPLIB,IGRP)
CALL LCMINF(KPLIB,TEXT12,TEXX12,EMPTY,ILONG,LCM)
CALL LCMLEN(KPLIB,'PROB-TABLE',LENG,ITYLCM)
NPART=LENG/MAXNOR
IF(LCM) THEN
CALL LCMGPD(KPLIB,'PROB-TABLE',SIGP_PTR)
CALL C_F_POINTER(SIGP_PTR,SIGP,(/ MAXNOR*NPART /))
ELSE
ALLOCATE(SIGP(MAXNOR*NPART))
CALL LCMGET(KPLIB,'PROB-TABLE',SIGP)
ENDIF
DO 30 INOR=1,NOR(JRES,IGRP)
WEIGH(INOR,JRES)=SIGP(INOR)
TOTPT(INOR,JRES)=SIGP(MAXNOR+INOR)
SIGWS(INOR,JRES)=SIGP(3*MAXNOR+INOR)
30 CONTINUE
IF(.NOT.LCM) DEALLOCATE(SIGP)
ELSE
WEIGH(1,JRES)=1.0
TOTPT(1,JRES)=STGAR(IPPT2(JRES,1),JRES,IGRP)
SIGWS(1,JRES)=SSGAR(IPPT2(JRES,1),JRES,1,IGRP)
ENDIF
40 CONTINUE
*----
* SET THE MIXTURE-DEPENDENT CROSS SECTIONS.
*----
DO 90 INOR=1,NORI
SIGTXS(0:NBMIX)=0.0
SIGS0X(0:NBMIX)=0.0
DO 80 IBM=1,NBMIX
IND=IREX(IBM)
DO 70 JRES=0,NIRES
IF(JRES.EQ.0) THEN
SIGTXS(IBM)=SIGTXS(IBM)+(SIGGAR(IBM,0,IGRP,1)-
1 SIGGAR(IBM,0,IGRP,2))
SIGS0X(IBM)=SIGS0X(IBM)-SIGGAR(IBM,0,IGRP,2)
ELSE IF((JRES.NE.IRES).AND.(IND.GT.0)) THEN
IF((IPPT2(IRES,2).EQ.IPPT2(JRES,2)).AND.
1 (IPPT2(IRES,3).EQ.IPPT2(JRES,3))) THEN
* FULL CORRELATION APPROXIMATION SIMILAR TO THE TECHNIQUE
* USED IN ECCO.
SIGTXS(IBM)=SIGTXS(IBM)+CONR(IND,JRES)*TOTPT(INOR,IRES)
SIGS0X(IBM)=SIGS0X(IBM)+(1.0-GOLD(JRES,IGRP))*
1 CONR(IND,JRES)*SIGWS(INOR,IRES)
ELSE
SIGTXS(IBM)=SIGTXS(IBM)+SIGGAR(IBM,JRES,IGRP,1)
ENDIF
ENDIF
70 CONTINUE
IF(IND.GT.0) THEN
SIGTXS(IBM)=SIGTXS(IBM)+CONR(IND,IRES)*TOTPT(INOR,IRES)
SIGS0X(IBM)=SIGS0X(IBM)+(1.0-GOLD(IRES,IGRP))*CONR(IND,IRES)
1 *SIGWS(INOR,IRES)
ENDIF
80 CONTINUE
IASM=IASM+1
NPSYS(IASM)=IASM
KPSYS=LCMDIL(IPSYS,IASM)
CALL LCMPUT(KPSYS,'DRAGON-TXSC',NBMIX+1,2,SIGTXS)
CALL LCMPUT(KPSYS,'DRAGON-S0XSC',NBMIX+1,2,SIGS0X)
90 CONTINUE
ELSE IF(GOLD(IRES,IGRP).GT.-900.) THEN
CALL LCMLEL(JPLI0,IGRP,LENG0,ITYLCM)
IF(LENG0.NE.0) THEN
WRITE(HSMG,'(42HUSSIT1: UNEXPECTED SELF-SHIELDING DATA FOU,
1 11HND IN GROUP,I5,1H.)') IGRP
CALL XABORT(HSMG)
ENDIF
ENDIF
100 CONTINUE
*----
* ASSEMBLY MATRIX OR REDUCED COLLISION PROBABILITIES CALCULATION.
*----
NANI=1
KNORM=1
NALBP=0
IMPY=MAX(0,IMPX-3)
IF(IPHASE.EQ.1) THEN
* USE A NATIVE DOOR.
ISTRM=1
NW=0
CALL DOORAV(CDOOR,IPSYS,NPSYS,IPTRK,IFTRAK,IMPY,NASM,NREG,
1 NBMIX,NANI,NW,MAT,VOL,KNORM,LEAKSW,TITR,NALBP,ISTRM)
ELSE IF(IPHASE.EQ.2) THEN
* USE A COLLISION PROBABILITY DOOR.
IPIJK=1
ITPIJ=1
CALL DOORPV(CDOOR,IPSYS,NPSYS,IPTRK,IFTRAK,IMPY,NASM,NREG,
1 NBMIX,NANI,MAT,VOL,KNORM,IPIJK,LEAKSW,ITPIJ,.FALSE.,TITR,
2 NALBP)
ENDIF
*----
* LOOP OVER THE ENERGY GROUPS.
*----
IASM=0
DO 260 IGRP=1,NGRP
IF(MASKG(IGRP).AND.(GOLD(IRES,IGRP).GT.-900.)) THEN
NORI=NOR(IRES,IGRP)
*----
* COLLECT THE BASE POINTS IN PARTIAL CROSS SECTION.
*----
DO 120 JRES=1,NIRES
JPLIB=LCMGID(IPPT1(JRES),'GROUP-PT')
CALL LCMLEL(JPLIB,IGRP,ILONG,ITYLCM)
IF(ILONG.NE.0) THEN
KPLIB=LCMGIL(JPLIB,IGRP)
CALL LCMINF(KPLIB,TEXT12,TEXX12,EMPTY,ILONG,LCM)
CALL LCMLEN(KPLIB,'PROB-TABLE',LENG,ITYLCM)
NPART=LENG/MAXNOR
IF(LCM) THEN
CALL LCMGPD(KPLIB,'PROB-TABLE',SIGP_PTR)
CALL C_F_POINTER(SIGP_PTR,SIGP,(/ MAXNOR*NPART /))
ELSE
ALLOCATE(SIGP(MAXNOR*NPART))
CALL LCMGET(KPLIB,'PROB-TABLE',SIGP)
ENDIF
DO 110 INOR=1,NOR(JRES,IGRP)
WEIGH(INOR,JRES)=SIGP(INOR)
SIGWS(INOR,JRES)=SIGP(3*MAXNOR+INOR)
110 CONTINUE
IF(.NOT.LCM) DEALLOCATE(SIGP)
ELSE
WEIGH(1,JRES)=1.0
SIGWS(1,JRES)=SSGAR(IPPT2(JRES,1),JRES,1,IGRP)
ENDIF
120 CONTINUE
*----
* RECOVER THE PREVIOUS FLUXES.
*----
WRITE(CBDPNM,'(3HCOR,I4.4,1H/,I4.4)') IRES,NIRES
CALL LCMSIX(IPLI0,CBDPNM,1)
JPLI0=LCMGID(IPLI0,'NWT0-PT')
CALL LCMLEL(JPLI0,IGRP,ILON,ITYLCM)
IF(ILON.GT.NBNRS*MAXNOR) THEN
WRITE(TEXT12,'(3A4)') (IPPT2(IRES,J0),J0=2,4)
WRITE(HSMG,'(34HUSSIT1: FLUX OVERFLOW FOR ISOTOPE ,A12)')
1 TEXT12
CALL XABORT(HSMG)
ENDIF
CALL LCMGDL(JPLI0,IGRP,XFLUX(1,1,IRES))
CALL LCMSIX(IPLI0,' ',2)
*----
* ITERATIVE PROCEDURE.
*----
ITER=0
140 ITER=ITER+1
IF(ITER.GT.MAXST) THEN
WRITE(HSMG,'(35HUSSIT1: TOO MANY ITERATIONS (MAXST=,I4,2H).)')
1 MAXST
CALL XABORT(HSMG)
ENDIF
ERR1=0.0
ERR2=0.0
*----
* COMPUTE THE AVERAGED SOURCE.
*----
ALLOCATE(FUN(NUN*NORI),SUN(NUN*NORI))
SUN(:NUN*NORI)=0.0
DO 195 INOR=1,NORI
KPSYS=LCMGIL(IPSYS,IASM+INOR)
CALL LCMLEN(KPSYS,'FUNKNO$USS',ILENG,ITYLCM)
IF(ILENG.EQ.NUN) THEN
CALL LCMGET(KPSYS,'FUNKNO$USS',FUN((INOR-1)*NUN+1))
ELSE
FUN((INOR-1)*NUN+1:INOR*NUN)=0.0
ENDIF
NPSYS(INOR)=IASM+INOR
SIGG(0)=0.0
DO 170 IBM=1,NBMIX
SIGG(IBM)=SIGGAR(IBM,0,IGRP,3)
IND=IREX(IBM)
DO 150 JRES=1,NIRES
IF((JRES.NE.IRES).AND.(IND.GT.0)) THEN
IF((IPPT2(IRES,2).EQ.IPPT2(JRES,2)).AND.
1 (IPPT2(IRES,3).EQ.IPPT2(JRES,3))) THEN
SIGG(IBM)=SIGG(IBM)+GOLD(JRES,IGRP)*SIGGAR(IBM,JRES,IGRP,4)
ELSE
SIGG(IBM)=SIGG(IBM)+SIGGAR(IBM,JRES,IGRP,4)
ENDIF
ENDIF
150 CONTINUE
IF(IND.GT.0) THEN
DO 160 JNOR=1,NORI
SIGG(IBM)=SIGG(IBM)+GOLD(IRES,IGRP)*WEIGH(JNOR,IRES)*
1 CONR(IND,IRES)*SIGWS(JNOR,IRES)*XFLUX(IND,JNOR,IRES)
160 CONTINUE
ENDIF
170 CONTINUE
IOF=(INOR-1)*NUN
CALL DOORS(CDOOR,IPTRK,NBMIX,0,NUN,SIGG,SUN(IOF+1))
195 CONTINUE
*----
* SOLVE FOR THE MULTIBAND FLUX.
*----
IDIR=0
LEXAC=.FALSE.
IPMACR=C_NULL_PTR
IPSOU=C_NULL_PTR
REBFLG=.FALSE.
CALL DOORFV(CDOOR,IPSYS,NPSYS,IPTRK,IFTRAK,IMPX,NORI,NBMIX,
1 IDIR,NREG,NUN,IPHASE,LEXAC,MAT,VOL,KEYFLX,TITR,SUN,FUN,IPMACR,
2 IPSOU,REBFLG)
*----
* HOMOGENIZE THE FLUX AT ITERATION ITER.
*----
UNGAR(:NUN,IRES,IGRP)=0.0
DO 235 INOR=1,NORI
KPSYS=LCMGIL(IPSYS,IASM+INOR)
CALL LCMPUT(KPSYS,'FUNKNO$USS',NUN,2,FUN((INOR-1)*NUN+1))
FLNEW(:NBNRS)=0.0
DO 200 I=1,NREG
IF(MAT(I).EQ.0) GO TO 200
IOF=(INOR-1)*NUN+KEYFLX(I)
IND=IREX(MAT(I))
IF(IND.GT.0) FLNEW(IND)=FLNEW(IND)+FUN(IOF)*VOL(I)
200 CONTINUE
DO 210 IND=1,NBNRS
FLNEW(IND)=FLNEW(IND)/VOLMER(IND)
210 CONTINUE
*
DO 220 I=1,NUN
IOF=(INOR-1)*NUN+I
UNGAR(I,IRES,IGRP)=UNGAR(I,IRES,IGRP)+FUN(IOF)*WEIGH(INOR,IRES)
220 CONTINUE
*----
* COMPUTE ERR1 AND ERR2.
*----
DO 230 IND=1,NBNRS
ERR1=MAX(ERR1,ABS(FLNEW(IND)-XFLUX(IND,INOR,IRES)))
ERR2=MAX(ERR2,ABS(FLNEW(IND)))
XFLUX(IND,INOR,IRES)=FLNEW(IND)
230 CONTINUE
235 CONTINUE
DEALLOCATE(SUN,FUN)
*----
* CONVERGENCE CONTROL.
*----
IF(IMPX.GT.2) THEN
WRITE(TEXT12,'(3A4)') (IPPT2(IRES,I),I=2,4)
WRITE(6,'(15H USSIT1: GROUP=,I5,24H. SUBGROUP ITERATION ITE,
1 6HRATION,I4,11H. ISOTOPE='',A12,9H''. ERROR=,1P,E11.4,1H.)')
2 IGRP,ITER,TEXT12,ERR1
ENDIF
IF((ERR1.GT.1.0E-4*ERR2).AND.(GOLD(IRES,IGRP).NE.0.0)) GO TO 140
IF(IMPX.GT.1) THEN
WRITE(TEXT12,'(3A4)') (IPPT2(IRES,I),I=2,4)
WRITE(6,'(15H USSIT1: GROUP=,I5,24H. SUBGROUP ITERATION CON,
1 11HVERGENCE IN,I4,22H ITERATIONS. ISOTOPE='',A12,2H''.)')
2 IGRP,ITER,TEXT12
ENDIF
IF(IMPX.GT.2) THEN
DO 250 IND=1,NBNRS
T1=0.0
DO 240 INOR=1,NORI
T1=T1+WEIGH(INOR,IRES)*XFLUX(IND,INOR,IRES)
240 CONTINUE
WRITE(6,'(31H USSIT1: AVERAGED FLUX IN GROUP,I4,9H AND RESO,
1 11HNANT REGION,I4,21H FOR RESONANT ISOTOPE,I4,2H =,F9.5)')
2 IGRP,IND,IRES,T1
250 CONTINUE
ENDIF
CALL LCMPDL(JPLI0,IGRP,NBNRS*NORI,2,XFLUX(1,1,IRES))
IASM=IASM+NORI
ENDIF
260 CONTINUE
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(FLNEW,SIGWS,TOTPT,WEIGH,SIGG,SIGS0X,SIGTXS,XFLUX)
DEALLOCATE(NPSYS)
RETURN
END
|
