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*DECK EDIALB
SUBROUTINE EDIALB(IPMAC2,IPFLUX,IPMACR,IPSYS,IPRINT,NBMIX,
1 NW,B2,NGROUP,NIFISS,NGCOND,ITRANC,ILEAKS,NREGIO,MATCOD,
2 VOLUME,KEYFLX,IGCOND,FLUXES,NMLEAK)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Compute boundary current from ALBS information for use with SPH
* equivalence techniques.
*
*Copyright:
* Copyright (C) 2011 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
* IPMAC2 pointer to condensed macrolib information (L_MACROLIB
* signature) built by EDI:.
* IPFLUX pointer to the reference solution (L_FLUX signature).
* IPMACR pointer to the reference macrolib (L_MACROLIB signature).
* IPSYS pointer to the reference pij LCM object (L_PIJ signature).
* IPRINT print index.
* NBMIX number of mixtures in the reference geometry.
* NW type of weighting for P1 cross section information:
* = 0 P0; = 1 P1.
* B2 square buckling array.
* For ILEAKS = 1 or 2, B2(4) is the homogeneous square buckling;
* for ILEAKS = 3, B2(1),B2(2),B2(3) are the directional
* heterogeneous and B2(4) is the homogeneous square buckling.
* NGROUP number of energy groups in the reference calculation.
* NIFISS number of fissile isotopes.
* NGCOND number of condensed groups.
* ITRANC type of transport correction.
* ILEAKS type of leakage calculation: =0: no leakage; =1: homogeneous
* leakage (Diffon); =2: isotropic streaming (Ecco);
* =3: anisotropic streaming (Tibere).
* NREGIO number of regions in the reference geometry.
* MATCOD mixture index in region.
* VOLUME volume of region.
* KEYFLX position of average fluxes.
* IGCOND limit of condensed groups.
* FLUXES fluxes.
* NMLEAK number of leakage zones.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPMAC2,IPFLUX,IPMACR,IPSYS
INTEGER IPRINT,NBMIX,NW,NGROUP,NIFISS,NGCOND,ITRANC,ILEAKS,
1 NREGIO,MATCOD(NREGIO),KEYFLX(NREGIO),IGCOND(NGCOND),NMLEAK
REAL B2(4),VOLUME(NREGIO),FLUXES(NREGIO,NGROUP,NW+1)
*----
* LOCAL VARIABLES
*----
TYPE(C_PTR) JPSYS,KPSYS,IPSYS2,JPMACR,KPMACR,JPFLUX
CHARACTER TEXT5*5,SUFF(2)*2
DOUBLE PRECISION SUM,SUD
INTEGER, ALLOCATABLE, DIMENSION(:) :: NJJ,IJJ,IPOS,IMERGL
REAL, ALLOCATABLE, DIMENSION(:) :: SIGMA,XSCAT,GAMMA,SIG1,WORKD
REAL, ALLOCATABLE, DIMENSION(:,:) :: DIFHET,COURIN,WORK
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: PRODUC
DATA SUFF/'00','01'/
*----
* SCRATCH STORAGE ALLOCATION
* COURIN ingoing currents (4*J-/S). PIS information must be available
* on LCM.
*----
ALLOCATE(NJJ(NBMIX),IJJ(NBMIX),IPOS(NBMIX))
ALLOCATE(COURIN(NGCOND,2),PRODUC(NREGIO,NGCOND,NIFISS))
ALLOCATE(WORK(NREGIO,2),SIGMA(0:NBMIX*NIFISS),XSCAT(NBMIX*NGROUP))
ALLOCATE(DIFHET(NMLEAK,NGROUP),IMERGL(NBMIX),GAMMA(NGROUP))
*----
* CONSISTENCY TESTS
*----
IF(.NOT.C_ASSOCIATED(IPSYS)) THEN
CALL XABORT('EDIALB: THE L_PIJ INFO IS NOT AVAILABLE.')
ENDIF
JPSYS=LCMGID(IPSYS,'GROUP')
KPSYS=LCMGIL(JPSYS,1)
CALL LCMLEN(KPSYS,'DRAGON-WIS',IXSLEN,ITYLCM)
IF(IXSLEN.NE.NREGIO) THEN
CALL LCMLIB(KPSYS)
WRITE(TEXT5,'(I5)') NREGIO
CALL XABORT('EDIALB: THE ALBS OPTION OF THE ASM: MODULE HAS NO'
> //'T BEEN ACTIVATED. NREGIO='//TEXT5)
ENDIF
*----
* COMPUTE THE FISSION RATE INFORMATION
*----
SIGMA(0)=0.0
PRODUC(:NREGIO,:NGCOND,:NIFISS)=0.0
IGRFIN=0
JPMACR=LCMGID(IPMACR,'GROUP')
DO 45 IGRCD=1,NGCOND
IGRDEB=IGRFIN+1
IGRFIN=IGCOND(IGRCD)
DO 40 IGR=IGRDEB,IGRFIN
KPMACR=LCMGIL(JPMACR,IGR)
CALL LCMLEN(KPMACR,'NUSIGF',ILCMLN,ITYLCM)
IF(ILCMLN.GT.0) THEN
CALL LCMGET(KPMACR,'NUSIGF',SIGMA(1))
DO 35 IFIS=1,NIFISS
DO 30 IREG=1,NREGIO
IBM=MATCOD(IREG)
IF(IBM.GT.0) THEN
SS=FLUXES(IREG,IGR,1)*SIGMA((IFIS-1)*NBMIX+IBM)
PRODUC(IREG,IGRCD,IFIS)=PRODUC(IREG,IGRCD,IFIS)+SS
ENDIF
30 CONTINUE
35 CONTINUE
ENDIF
40 CONTINUE
45 CONTINUE
CALL LCMLEN(IPFLUX,'K-EFFECTIVE',ILCMLN,ITYLCM)
IF(ILCMLN.EQ.1) THEN
CALL LCMGET(IPFLUX,'K-EFFECTIVE',EIGENK)
ELSE
EIGENK=1.0
ENDIF
IF(IPRINT.GT.5) WRITE(6,'(/16H EDIALB: EIGENK=,1P,E12.4)') EIGENK
*----
* COMPUTE MERGED/CONDENSED CROSS SECTIONS
*----
IF(ILEAKS.EQ.1) THEN
CALL LCMLEN(IPFLUX,'DIFFHET',ILCMLN,ITYLCM)
IF(ILCMLN.EQ.0) THEN
CALL XABORT('EDIALB: UNABLE TO RECOVER THE DIFFHET RECORD IN'
> //' THE FLUX OBJECT.')
ENDIF
CALL LCMGET(IPFLUX,'IMERGE-LEAK',IMERGL)
CALL LCMGET(IPFLUX,'DIFFHET',DIFHET)
ENDIF
IF(NW.EQ.1) CALL LCMGET(IPFLUX,'GAMMA',GAMMA)
CALL LCMSIX(IPMAC2,'ADF',1)
DO 180 INL=1,NW+1
IGRFIN=0
DO 175 IGRCD=1,NGCOND
COURIN(IGRCD,:2)=0.0
IGRDEB=IGRFIN+1
IGRFIN=IGCOND(IGRCD)
IF((ILEAKS.EQ.2).OR.(ILEAKS.EQ.3)) THEN
CALL LCMLEN(IPFLUX,'FLUX',ILON,ITYLCM)
IF(ILON.EQ.0) CALL XABORT('EDIALB: MISSING FLUX INFO.')
JPFLUX=LCMGID(IPFLUX,'FLUX')
ENDIF
DO 170 IGR=IGRDEB,IGRFIN
KPMACR=LCMGIL(JPMACR,IGR)
CALL LCMLEN(KPMACR,'NTOT0',ILCMLN,ITYLCM)
IF(ILCMLN.GT.0) THEN
CALL LCMGET(KPMACR,'NTOT0',SIGMA(1))
ELSE
CALL XABORT('EDIALB: READ ERROR ON LCM RECORD= TOTAL.')
ENDIF
IF((ITRANC.NE.0).AND.(INL.EQ.1)) THEN
* TRANSPORT CORRECTION.
ALLOCATE(SIG1(NBMIX))
CALL LCMGET(KPMACR,'TRANC',SIG1)
DO 50 IMAT=1,NBMIX
SIGMA(IMAT)=SIGMA(IMAT)-SIG1(IMAT)
50 CONTINUE
DEALLOCATE(SIG1)
ENDIF
IF((ILEAKS.EQ.2).OR.(ILEAKS.EQ.3)) THEN
CALL LCMLEL(JPFLUX,IGR,ILCMLN,ITYLCM)
IF(ILCMLN.EQ.0) CALL XABORT('EDIALB: MISSING FLUX INFO.')
ALLOCATE(WORKD(ILCMLN))
CALL LCMGDL(JPFLUX,IGR,WORKD)
ENDIF
ZNUM=0.0
IF((NW.EQ.1).AND.(INL.EQ.2)) THEN
* USE WITH THE FUNDAMENTAL CURRENT EQUATION OF THE ECCO MODEL.
ZDEN=0.0
DO 55 IREG=1,NREGIO
IBM=MATCOD(IREG)
ZNUM=ZNUM+SIGMA(IBM)*FLUXES(IREG,IGR,1)*VOLUME(IREG)
ZDEN=ZDEN+FLUXES(IREG,IGR,1)*VOLUME(IREG)
55 CONTINUE
ZNUM=ZNUM/ZDEN
ENDIF
DO 60 IREG=1,NREGIO
IBM=MATCOD(IREG)
ZLEAK=0.0
IF((NW.EQ.1).AND.(INL.EQ.1)) THEN
ZLEAK=B2(4)*FLUXES(IREG,IGR,2)
ELSE IF((NW.EQ.1).AND.(INL.EQ.2)) THEN
ZLEAK=(-(1.0-GAMMA(IGR))*(ZNUM-SIGMA(IBM))*FLUXES(IREG,IGR,2)
> -FLUXES(IREG,IGR,1)/3.0)/GAMMA(IGR)
ELSE IF(ILEAKS.EQ.1) THEN
IME=IMERGL(IBM)
IF(IME.GT.0) ZLEAK=DIFHET(IME,IGR)*B2(4)*FLUXES(IREG,IGR,1)
ELSE IF(ILEAKS.EQ.2) THEN
ZLEAK=B2(4)*WORKD(KEYFLX(IREG)+ILCMLN/2)
ELSE IF(ILEAKS.EQ.3) THEN
ZLEAK=B2(1)*WORKD(KEYFLX(IREG)+ILCMLN/4)+
> B2(2)*WORKD(KEYFLX(IREG)+ILCMLN/2)+
> B2(3)*WORKD(KEYFLX(IREG)+3*ILCMLN/4)
ENDIF
WORK(IREG,1)=-ZLEAK
60 CONTINUE
IF((ILEAKS.EQ.2).OR.(ILEAKS.EQ.3)) DEALLOCATE(WORKD)
*
CALL LCMLEN(KPMACR,'CHI',ILCMLN,ITYLCM)
IF((ILCMLN.GT.0).AND.(INL.EQ.1)) THEN
DO 85 IFIS=1,NIFISS
CALL LCMGET(KPMACR,'CHI',SIGMA(1))
DO 80 IREG=1,NREGIO
IBM=MATCOD(IREG)
IF(IBM.GT.0) THEN
DO 70 JGRCD=1,NGCOND
SS=SIGMA((IFIS-1)*NBMIX+IBM)*PRODUC(IREG,JGRCD,IFIS)/EIGENK
WORK(IREG,1)=WORK(IREG,1)+SS
70 CONTINUE
ENDIF
80 CONTINUE
85 CONTINUE
ENDIF
*
CALL LCMLEN(KPMACR,'SIGW'//SUFF(INL),ILCMLN,ITYLCM)
IF(ILCMLN.GT.0) THEN
CALL LCMGET(KPMACR,'SIGW'//SUFF(INL),SIGMA(1))
ELSE
SIGMA(:NBMIX)=0.0
ENDIF
IF((ITRANC.NE.0).AND.(INL.EQ.1)) THEN
* TRANSPORT CORRECTION.
ALLOCATE(SIG1(NBMIX))
CALL LCMGET(KPMACR,'TRANC',SIG1)
DO 120 IMAT=1,NBMIX
SIGMA(IMAT)=SIGMA(IMAT)-SIG1(IMAT)
120 CONTINUE
DEALLOCATE(SIG1)
ENDIF
CALL LCMLEN(KPMACR,'NJJS'//SUFF(INL),ILCMLN,ITYLCM)
IF(ILCMLN.GT.0) THEN
CALL LCMGET(KPMACR,'NJJS'//SUFF(INL),NJJ)
CALL LCMGET(KPMACR,'IJJS'//SUFF(INL),IJJ)
CALL LCMGET(KPMACR,'IPOS'//SUFF(INL),IPOS)
CALL LCMGET(KPMACR,'SCAT'//SUFF(INL),XSCAT)
DO 150 IREG=1,NREGIO
IBM=MATCOD(IREG)
IF(IBM.GT.0) THEN
JGRFIN=0
DO 140 JGRCD=1,NGCOND
SS=0.0D0
JGRDEB=JGRFIN+1
JGRFIN=IGCOND(JGRCD)
J2=MIN(JGRFIN,IJJ(IBM))
J1=MAX(JGRDEB,IJJ(IBM)-NJJ(IBM)+1)
IPO=IPOS(IBM)+IJJ(IBM)-J2
DO 130 JGR=J2,J1,-1
IF(IGR.EQ.JGR) THEN
SS=SS+SIGMA(IBM)*FLUXES(IREG,JGR,INL)
ELSE
SS=SS+XSCAT(IPO)*FLUXES(IREG,JGR,INL)
ENDIF
IPO=IPO+1
130 CONTINUE
IF(INL.EQ.2) SS=SS/GAMMA(IGR)
WORK(IREG,1)=WORK(IREG,1)+SS
140 CONTINUE
ENDIF
150 CONTINUE
ENDIF
*----
* COMPUTE BOUNDARY CURRENTS
*----
IF(INL.EQ.1) THEN
JPSYS=LCMGID(IPSYS,'GROUP')
ELSE IF(INL.EQ.2) THEN
IPSYS2=LCMGID(IPSYS,'STREAMING')
JPSYS=LCMGID(IPSYS2,'GROUP')
ENDIF
KPSYS=LCMGIL(JPSYS,IGR)
CALL LCMLEN(KPSYS,'DRAGON-WIS',ILCMLN,ITYLCM)
IF(ILCMLN.EQ.NREGIO) THEN
CALL LCMGET(KPSYS,'DRAGON-WIS',WORK(1,2))
CALL LCMGET(KPSYS,'DRAGON-TXSC',SIGMA(0))
SUM=0.0D0
SUD=0.0D0
DO 160 IREG=1,NREGIO
FACTOR=VOLUME(IREG)
IBM=MATCOD(IREG)
SUM=SUM+SIGMA(IBM)*FACTOR*FLUXES(IREG,IGR,1)
> -WORK(IREG,1)*FACTOR*(1.0-WORK(IREG,2))
SUD=SUD+SIGMA(IBM)*FACTOR*WORK(IREG,2)
160 CONTINUE
COURIN(IGRCD,:2)=COURIN(IGRCD,:2)+REAL(SUM/SUD)
ENDIF
170 CONTINUE
175 CONTINUE
CALL LCMPUT(IPMAC2,'ALBS'//SUFF(INL),NGCOND*2,2,COURIN)
IF(IPRINT.GT.3) THEN
WRITE(6,900) SUFF(INL),(COURIN(IGR,1),IGR=1,NGCOND)
WRITE(6,'(/)')
ENDIF
180 CONTINUE
CALL LCMSIX(IPMAC2,' ',2)
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(GAMMA,IMERGL,DIFHET,XSCAT,SIGMA,WORK,PRODUC,COURIN)
DEALLOCATE(IPOS,IJJ,NJJ)
RETURN
*
900 FORMAT(/10H EDIALB: P,A2,36H IN-CURRENTS (4J-/S) PER MACRO-GROUP,
> 5HS ARE/(1X,1P,10E13.5))
END
|
