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|
*DECK DREKOU
SUBROUTINE DREKOU(IPRINT,IPGPT,IPMAC1,IPMAC2,IPFLX,IPTRK,IPGRAD,
1 NG,NREG,ITYPE,IELEM,NMIL,NALBP,NUN,NFIS1,NFIS2,ILEAK1,ILEAK2,
2 IDF2,MATCOD,KEYFLX,VOL,LNO,RMSD)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Compute the GPT sources corresponding to the gradient of the RMS
* absorption distribution. Case with direct effect.
*
*Copyright:
* Copyright (C) 2017 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
* IPRINT print parameter
* IPGPT pointer to the L_SOURCE data structure.
* IPMAC1 pointer to the actual macrolib structure.
* IPMAC2 pointer to the reference macrolib structure.
* IPFLX pointer to the multigroup flux.
* IPTRK pointer to the tracking object.
* IPGRAD pointer to the L_OPTIMIZE object.
* NG number of energy groups.
* NREG number of regions.
* NMIL number of material mixtures.
* NALBP number of physical albedos.
* NUN number of unknowns per energy group.
* NFIS1 number of fissile isotopes in actual macrolib.
* NFIS2 number of fissile isotopes in reference macrolib.
* ILEAK1 type of leakage calculation in actual macrolib
* =0: no leakage; =1: homogeneous leakage (Diffon).
* ILEAK2 type of leakage calculation in reference macrolib.
* IDF2 ADF type, 0 = none, 1 = Albedo, 2 = FD_B/FD_C/..., 3 = ADF.
* MATCOD material mixture indices per region.
* KEYFLX position of averaged fluxes in unknown vector.
* VOL volumes.
* LNO flag set to .true. to exit after calculation of RMS.
*
*Parameters: output
* RMSD RMS error on rate distribution.
*
*Parameters:
* ITYPE
* IELEM
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPGPT,IPMAC1,IPMAC2,IPFLX,IPTRK,IPGRAD
INTEGER IPRINT,NG,NREG,ITYPE,IELEM,NMIL,NALBP,NUN,NFIS1,NFIS2,
> ILEAK1,ILEAK2,IDF2,MATCOD(NREG),KEYFLX(NREG)
REAL VOL(NREG)
DOUBLE PRECISION RMSD
LOGICAL LNO
*----
* LOCAL VARIABLES
*----
PARAMETER (NSTATE=40)
TYPE(C_PTR) JPMAC1,JPMAC2,KPMAC1,KPMAC2,JPFLX,JPGPT,KPGPT
INTEGER ISTATE(NSTATE)
DOUBLE PRECISION SOUT1,SOUT2,GRATOT,SOUTOT,AB1TOT,AB2TOT,FI1TOT,
> FI2TOT,SUM1,DSUM,DELTA,OUT,SA,SF,SUNGAR,ABS2M,OUT2M,AIL,BIL,DEN1,
> DEN2
CHARACTER HSMG*131
DOUBLE PRECISION, PARAMETER :: EPS=1.0E-4,EPSL=1.0E-4
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:) :: IJJ,NJJ,IPOS,IREL,KN,IQFR
REAL, ALLOCATABLE, DIMENSION(:) :: GAR,WORK,SUNK,FLUX,QFR,OUTG1,
> OUTG2,DIFHOM,DIFF
REAL, ALLOCATABLE, DIMENSION(:,:) :: PHI1,PHI2,ABS1,ABS2,NUF1,
> NUF2,GAMMA,OUTG2R
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: CHI1,CHI2,RHS1,LHS1,RHS2,
> LHS2
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:) :: VARV,GRAD,RHS,CONST
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:) :: SIGA,SIGF
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(PHI1(NMIL,NG),PHI2(NMIL,NG),ABS1(NMIL,NG),ABS2(NMIL,NG),
1 RHS1(NMIL,NG,NG),LHS1(NMIL,NG,NG),RHS2(NMIL,NG,NG),
2 LHS2(NMIL,NG,NG),CONST(NG),IREL(NG),RHS(NG),GAMMA(NUN,NG),
3 OUTG1(NG),OUTG2(NG),OUTG2R(NG,2),SIGA(NMIL,NG),SIGF(NMIL,NG))
*----
* COMPUTE THE ACTUAL AND REFERENCE REACTION RATE MATRICES
*----
CALL LCMGET(IPMAC1,'K-EFFECTIVE',ZKEFF1)
CALL LCMGET(IPMAC2,'K-EFFECTIVE',ZKEFF2)
IF(IDF2.EQ.1) THEN
CALL LCMSIX(IPMAC2,'ADF',1)
CALL LCMLEN(IPMAC2,'ALBS00',ILCMLN,ITYLCM)
IF(ILCMLN.NE.2*NG) CALL XABORT('DREKOU: WRONG ALBS00 LENGTH.')
CALL LCMGET(IPMAC2,'ALBS00',OUTG2R)
CALL LCMSIX(IPMAC2,' ',2)
ENDIF
CALL LCMLEN(IPMAC1,'B2 B1HOM',ILCMLN,ITYLCM)
IF(ILCMLN.EQ.1) THEN
CALL LCMGET(IPMAC1,'B2 B1HOM',B21)
ELSE
B21=0.0
ENDIF
CALL LCMLEN(IPMAC2,'B2 B1HOM',ILCMLN,ITYLCM)
IF(ILCMLN.EQ.1) THEN
CALL LCMGET(IPMAC2,'B2 B1HOM',B22)
ELSE
B22=0.0
ENDIF
IF((ILEAK1.EQ.1).AND.(IPRINT.GT.0)) THEN
WRITE(6,'(/22H DREKOU: MACRO B2=,1P,E12.4)') B21
ENDIF
IF((ILEAK2.EQ.1).AND.(IPRINT.GT.0)) THEN
WRITE(6,'(/22H DREKOU: REFERENCE B2=,1P,E12.4)') B22
ENDIF
RHS1(:NMIL,:NG,:NG)=0.0
LHS1(:NMIL,:NG,:NG)=0.0
RHS2(:NMIL,:NG,:NG)=0.0
LHS2(:NMIL,:NG,:NG)=0.0
SIGA(:NMIL,:NG)=0.0D0
SIGF(:NMIL,:NG)=0.0D0
JPMAC1=LCMGID(IPMAC1,'GROUP')
JPMAC2=LCMGID(IPMAC2,'GROUP')
ALLOCATE(IJJ(NMIL),NJJ(NMIL),IPOS(NMIL),GAR(NMIL),WORK(NMIL*NG),
1 CHI1(NMIL,NFIS1,NG),NUF1(NMIL,NFIS1),CHI2(NMIL,NFIS2,NG),
2 NUF2(NMIL,NFIS2),DIFHOM(NG),DIFF(NMIL))
DO IG=1,NG
KPMAC1=LCMGIL(JPMAC1,IG)
CALL LCMGET(KPMAC1,'CHI',CHI1(1,1,IG))
KPMAC2=LCMGIL(JPMAC2,IG)
CALL LCMGET(KPMAC2,'CHI',CHI2(1,1,IG))
CALL LCMLEN(KPMAC1,'FLUX-INTG',ILG,ITYLCM)
IF(ILG.NE.NMIL) CALL XABORT('DREKOU: MISSING ACTUAL FLUX.')
CALL LCMLEN(KPMAC2,'FLUX-INTG',ILG,ITYLCM)
IF(ILG.NE.NMIL) CALL XABORT('DREKOU: MISSING REFERENCE FLUX.')
CALL LCMGET(KPMAC1,'FLUX-INTG',PHI1(1,IG))
CALL LCMGET(KPMAC2,'FLUX-INTG',PHI2(1,IG))
ENDDO
DO IG=1,NG
KPMAC1=LCMGIL(JPMAC1,IG)
KPMAC2=LCMGIL(JPMAC2,IG)
IF(ILEAK1.EQ.1) THEN
CALL LCMLEN(KPMAC1,'DIFF',ILCMLN,ITYLCM)
IF(ILCMLN.GT.0) THEN
CALL LCMGET(KPMAC1,'DIFF',DIFF)
ELSE
CALL LCMGET(IPMAC1,'DIFHOMB1HOM',DIFHOM)
DO IBM=1,NMIL
DIFF(IBM)=DIFHOM(IG)
ENDDO
ENDIF
ELSE
DIFF(:NMIL)=0.0
ENDIF
CALL LCMGET(KPMAC1,'NTOT0',GAR)
CALL LCMGET(KPMAC1,'SCAT00',WORK)
CALL LCMGET(KPMAC1,'NJJS00',NJJ)
CALL LCMGET(KPMAC1,'IJJS00',IJJ)
CALL LCMGET(KPMAC1,'IPOS00',IPOS)
DO IBM=1,NMIL
SIGA(IBM,IG)=SIGA(IBM,IG)+GAR(IBM)
IPOSDE=IPOS(IBM)
DO JG=IJJ(IBM),IJJ(IBM)-NJJ(IBM)+1,-1
* IG <-- JG
RHS1(IBM,IG,JG)=RHS1(IBM,IG,JG)-WORK(IPOSDE)*PHI1(IBM,JG)
SIGA(IBM,JG)=SIGA(IBM,JG)-WORK(IPOSDE)
IPOSDE=IPOSDE+1
ENDDO
RHS1(IBM,IG,IG)=RHS1(IBM,IG,IG)+(GAR(IBM)+B21*DIFF(IBM))*
> PHI1(IBM,IG)
ENDDO
CALL LCMGET(KPMAC1,'NUSIGF',NUF1)
DO IBM=1,NMIL
DO IFIS=1,NFIS1
DO JG=1,NG
LHS1(IBM,JG,IG)=LHS1(IBM,JG,IG)+CHI1(IBM,IFIS,JG)*
> NUF1(IBM,IFIS)*PHI1(IBM,IG)
SIGF(IBM,IG)=SIGF(IBM,IG)+CHI1(IBM,IFIS,JG)*NUF1(IBM,IFIS)
ENDDO
ENDDO
ENDDO
*
IF(ILEAK2.EQ.1) THEN
CALL LCMLEN(KPMAC2,'DIFF',ILCMLN,ITYLCM)
IF(ILCMLN.GT.0) THEN
CALL LCMGET(KPMAC2,'DIFF',DIFF)
ELSE
CALL LCMGET(IPMAC2,'DIFHOMB1HOM',DIFHOM)
DO IBM=1,NMIL
DIFF(IBM)=DIFHOM(IG)
ENDDO
ENDIF
ELSE
DIFF(:NMIL)=0.0
ENDIF
CALL LCMGET(KPMAC2,'NTOT0',GAR)
CALL LCMGET(KPMAC2,'SCAT00',WORK)
CALL LCMGET(KPMAC2,'NJJS00',NJJ)
CALL LCMGET(KPMAC2,'IJJS00',IJJ)
CALL LCMGET(KPMAC2,'IPOS00',IPOS)
DO IBM=1,NMIL
IPOSDE=IPOS(IBM)
DO JG=IJJ(IBM),IJJ(IBM)-NJJ(IBM)+1,-1
* IG <-- JG
RHS2(IBM,IG,JG)=RHS2(IBM,IG,JG)-WORK(IPOSDE)*PHI2(IBM,JG)
IPOSDE=IPOSDE+1
ENDDO
RHS2(IBM,IG,IG)=RHS2(IBM,IG,IG)+(GAR(IBM)+B22*DIFF(IBM))*
> PHI2(IBM,IG)
ENDDO
CALL LCMGET(KPMAC2,'NUSIGF',NUF2)
DO IBM=1,NMIL
DO IFIS=1,NFIS2
DO JG=1,NG
LHS2(IBM,JG,IG)=LHS2(IBM,JG,IG)+CHI2(IBM,IFIS,JG)*
> NUF2(IBM,IFIS)*PHI2(IBM,IG)
ENDDO
ENDDO
ENDDO
ENDDO
DEALLOCATE(DIFF,DIFHOM,NUF2,CHI2,NUF1,CHI1,WORK,GAR,IPOS,NJJ,IJJ)
*----
* COMPUTE THE ACTUAL AND REFERENCE ABSORPTION AND FISSION RATES
*----
AB1TOT=0.0D0
AB2TOT=0.0D0
FI1TOT=0.0D0
FI2TOT=0.0D0
DO IG=1,NG
OUTG1(IG)=0.0
OUTG2(IG)=0.0
DO IBM=1,NMIL
OUTG1(IG)=OUTG1(IG)+SUM(LHS1(IBM,IG,:NG))/ZKEFF1-
1 SUM(RHS1(IBM,IG,:NG))
OUTG2(IG)=OUTG2(IG)+SUM(LHS2(IBM,IG,:NG))/ZKEFF2-
1 SUM(RHS2(IBM,IG,:NG))
ABS1(IBM,IG)=SUM(RHS1(IBM,:NG,IG))
ABS2(IBM,IG)=SUM(RHS2(IBM,:NG,IG))
AB1TOT=AB1TOT+ABS1(IBM,IG)
AB2TOT=AB2TOT+ABS2(IBM,IG)
FI1TOT=FI1TOT+SUM(LHS1(IBM,:NG,IG))
FI2TOT=FI2TOT+SUM(LHS2(IBM,:NG,IG))
ENDDO
IF(IDF2.EQ.1) OUTG2(IG)=OUTG2R(IG,1)-OUTG2R(IG,2)
IF((NALBP.GT.0).AND.(OUTG2(IG).LT.-1.0E-6)) THEN
WRITE(HSMG,'(44HDREKOU: INCONSISTENT REFERENCE LEAKAGE IN GR,
1 3HOUP,I4,7H. LEAK=,1P,E13.4)') IG,OUTG2(IG)
CALL XABORT(HSMG)
ENDIF
ENDDO
*----
* COMPUTE THE ACTUAL LEAKAGE FROM OUT-CURRENTS
*----
OUT=0.0D0
GAMMA(:NUN,:NG)=0.0
IF(NALBP.GT.0) THEN
CALL LCMLEN(IPTRK,'KN',MAXKN,ITYLCM)
CALL LCMLEN(IPTRK,'QFR',MAXQF,ITYLCM)
ALLOCATE(KN(MAXKN),QFR(MAXQF),IQFR(MAXQF),FLUX(NUN))
CALL LCMGET(IPTRK,'KN',KN)
CALL LCMGET(IPTRK,'QFR',QFR)
CALL LCMGET(IPTRK,'IQFR',IQFR)
JPFLX=LCMGID(IPFLX,'FLUX')
DO IG=1,NG
CALL LCMGDL(JPFLX,IG,FLUX)
CALL DREJ02(ITYPE,IELEM,NREG,NUN,MAXKN,MAXQF,MATCOD,KN,QFR,
1 IQFR,VOL,FLUX,OUTG1(IG),GAMMA(1,IG))
OUT=OUT+OUTG1(IG)
IF(IPRINT.GT.0) WRITE(6,130) IG,OUTG1(IG)/REAL(AB1TOT),
1 OUTG2(IG)/REAL(AB2TOT)
ENDDO
DEALLOCATE(FLUX,IQFR,QFR,KN)
ENDIF
*----
* COMPUTE MACRO AND REFERENCE K-EFFECTIVE
*----
DEN1=0.0D0
DEN2=0.0D0
DO IG=1,NG
OUTG1(IG)=OUTG1(IG)+SUM(ABS1(:NMIL,IG))
OUTG2(IG)=OUTG2(IG)+SUM(ABS2(:NMIL,IG))
DEN1=DEN1+OUTG1(IG)
DEN2=DEN2+OUTG2(IG)
ENDDO
IF(IPRINT.GT.0) THEN
WRITE(6,'(/24H DREKOU: MACRO KEFF=,1P,E12.5)') FI1TOT/DEN1
WRITE(6,'(/24H DREKOU: REFERENCE KEFF=,1P,E12.5)') FI2TOT/DEN2
ENDIF
*----
* GET INFORMATION FROM L_OPTIMIZE OBJECT
*----
CALL LCMGET(IPGRAD,'DEL-STATE',ISTATE)
IF(ISTATE(4).LE.2) CALL XABORT('DREKOU: NO DIRECT EFFECT WITH '
> //'THIS TYPE OF PERTURBATION.')
IF(ISTATE(7).NE.1) CALL XABORT('DREKOU: IBM1=1 EXPECTED.')
IF(ISTATE(8).NE.NMIL) CALL XABORT('DREKOU: IBM2=NMIL EXPECTED.')
IMC=ISTATE(4)-2
NGR1=ISTATE(5)
NGR2=ISTATE(6)
IF(IMC.LE.2) THEN
NPERT=(NMIL+NALBP)*(NGR2-NGR1+1)
ELSE
NPERT=NALBP*(NGR2-NGR1+1)
ENDIF
ALLOCATE(VARV(NPERT))
CALL LCMGET(IPGRAD,'VAR-VALUE',VARV)
*----
* COMPUTE THE RMS FUNCTIONAL AND CONSTRAINTS
*----
IREL(:NGR2-NGR1+1)=0
RHS(:NGR2-NGR1+1)=0.0D0
WEI=REAL(NMIL)
RMSD=0.0D0
IF(IMC.LE.2) THEN
IPERT=0
DO IG=NGR1,NGR2
SUM1=0.0D0
DSUM=0.0D0
DO IBM=1,NMIL
IPERT=IPERT+1
ABS2M=MAX(EPS*AB2TOT,DBLE(ABS2(IBM,IG)))
DELTA=ABS1(IBM,IG)*AB2TOT/(ABS2M*AB1TOT)-ABS2(IBM,IG)/ABS2M
RMSD=RMSD+DELTA**2
SUM1=SUM1+PHI2(IBM,IG)/VARV(IPERT)
DSUM=DSUM+PHI2(IBM,IG)
ENDDO
DELTA=SUM1/DSUM-1.0D0
RMSD=RMSD+DELTA**2
CONST(IG-NGR1+1)=DELTA
IPERT=IPERT+NALBP
ENDDO
ENDIF
IF(NALBP.GT.0) THEN
DO IG=1,NG
OUT2M=MAX(EPSL*FI2TOT,DBLE(OUTG2(IG)))
DELTA=OUTG1(IG)*FI2TOT/(OUT2M*FI1TOT)-OUTG2(IG)/OUT2M
RMSD=RMSD+WEI*DELTA**2
ENDDO
ENDIF
IF(IPRINT.GT.0) THEN
WRITE(6,100) RMSD
IF(IMC.LE.2) THEN
DO IG=NGR1,NGR2
WRITE(6,110) IG,CONST(IG-NGR1+1)
ENDDO
ENDIF
ENDIF
IF((IPRINT.GT.2).AND.(IMC.LE.2)) THEN
DO IG=1,NG
WRITE(6,'(7H GROUP=,I4)') IG
DO IBM=1,NMIL
WRITE(6,120) IBM,ABS1(IBM,IG)/REAL(AB1TOT),
1 ABS2(IBM,IG)/REAL(AB2TOT)
ENDDO
ENDDO
ENDIF
*----
* STORE INFORMATION ON L_OPTIMIZE OBJECT
*----
CALL LCMPUT(IPGRAD,'FOBJ-CST-VAL',1,4,RMSD)
IF(LNO) GO TO 20
*----
* COMPUTE THE GRADIENT OF THE RMS FUNCTIONAL
*----
ALLOCATE(SUNK(NUN))
JPGPT=LCMLID(IPGPT,'ASOUR',1)
KPGPT=LCMLIL(JPGPT,1,NG)
DO IG=1,NG
SUNK(:NUN)=0.0
DO IR=1,NREG
IUNK=KEYFLX(IR)
IF(IUNK.EQ.0) CYCLE
IBM=MATCOD(IR)
IF(IBM.EQ.0) CYCLE
SA=SIGA(IBM,IG)
SF=SIGF(IBM,IG)
SOUT1=0.0D0
SOUT2=0.0D0
SUNGAR=0.0D0
IF(IMC.LE.2) THEN
DO JG=1,NG
DO JBM=1,NMIL
ABS2M=MAX(EPS*AB2TOT,DBLE(ABS2(JBM,JG)))
DELTA=ABS1(JBM,JG)*AB2TOT/(ABS2M*AB1TOT)-ABS2(JBM,JG)/
1 ABS2M
IF((IG.EQ.JG).AND.(IBM.EQ.JBM)) THEN
SOUT1=SOUT1+DELTA/ABS2M
ENDIF
SOUT2=SOUT2+(ABS1(JBM,JG)/AB1TOT)*DELTA/ABS2M
ENDDO
ENDDO
SUNGAR=2.0D0*VOL(IR)*SA*AB2TOT*(SOUT1-SOUT2)/AB1TOT
ENDIF
IF(NALBP.GT.0) THEN
SOUT1=0.0D0
SOUT2=0.0D0
DO JG=1,NG
OUT2M=MAX(EPSL*FI2TOT,DBLE(OUTG2(JG)))
DELTA=OUTG1(JG)*FI2TOT/(OUT2M*FI1TOT)-OUTG2(JG)/OUT2M
IF(IG.EQ.JG) SOUT1=SOUT1+DELTA*SA/OUT2M
SOUT2=SOUT2+(OUTG1(JG)/FI1TOT)*DELTA*SF/OUT2M
ENDDO
SUNGAR=SUNGAR+2.0D0*VOL(IR)*WEI*FI2TOT*(SOUT1-SOUT2)/FI1TOT
ENDIF
SUNK(IUNK)=REAL(SUNGAR)
ENDDO
IF(NALBP.GT.0) THEN
OUT2M=MAX(EPSL*FI2TOT,DBLE(OUTG2(IG)))
DELTA=OUTG1(IG)*FI2TOT/(OUT2M*FI1TOT)-OUTG2(IG)/OUT2M
DO IUNK=1,NUN
SOUT1=DELTA*GAMMA(IUNK,IG)/OUT2M
SUNK(IUNK)=SUNK(IUNK)+2.0*WEI*REAL(FI2TOT*SOUT1/FI1TOT)
ENDDO
ENDIF
CALL LCMPDL(KPGPT,IG,NUN,2,SUNK)
ENDDO
*----
* CHECK SOURCE ORTHOGONALITY
*----
ALLOCATE(FLUX(NUN))
JPFLX=LCMGID(IPFLX,'FLUX')
AIL=0.0D0
BIL=0.0D0
DO IG=1,NG
CALL LCMGDL(KPGPT,IG,SUNK)
CALL LCMGDL(JPFLX,IG,FLUX)
DO IUNK=1,NUN
GAZ=FLUX(IUNK)*SUNK(IUNK)
DAZ=FLUX(IUNK)**2
AIL=AIL+GAZ
BIL=BIL+DAZ
ENDDO
ENDDO
DSUM=ABS(AIL)/ABS(BIL)/REAL(NUN)
IF(IPRINT.GT.0) THEN
WRITE(6,'(/21H DREKOU: DOT PRODUCT=,1P,E11.4)') DSUM
ENDIF
IF(ABS(DSUM).GT.1.0E-4) THEN
WRITE(HSMG,'(36HDREKOU: NON ORTHOGONAL SOURCE (DSUM=,1P,E11.3,
1 2H).)') DSUM
CALL XABORT(HSMG)
ENDIF
DEALLOCATE(FLUX,SUNK)
*----
* COMPUTE THE DIRECT GRADIENTS
*----
ALLOCATE(GRAD(NPERT))
GRAD(:NPERT)=0.0D0
IF(IMC.GT.2) GO TO 10
IPERT=0
DO IG=NGR1,NGR2
DSUM=0.0D0
DO IBM=1,NMIL
DSUM=DSUM+PHI2(IBM,IG)
ENDDO
DO IBM=1,NMIL
IPERT=IPERT+1
GRATOT=0.0D0
DO JG=1,NG
DO JBM=1,NMIL
SOUTOT=0.0D0
IF((IG.EQ.JG).AND.(IBM.EQ.JBM)) SOUTOT=1.0
SOUTOT=SOUTOT-ABS1(IBM,IG)/AB1TOT
ABS2M=MAX(EPS*AB2TOT,DBLE(ABS2(JBM,JG)))
DELTA=ABS1(JBM,JG)*AB2TOT/(ABS2M*AB1TOT)-ABS2(JBM,JG)/ABS2M
GRATOT=GRATOT+SOUTOT*ABS1(JBM,JG)*DELTA*AB2TOT/ABS2M
ENDDO
ENDDO
GRAD(IPERT)=2.0D0*GRATOT/AB1TOT/VARV(IPERT)
IF(NALBP.GT.0) THEN
SOUT1=0.0D0
SOUT2=0.0D0
DO JG=1,NG
OUT2M=MAX(EPSL*FI2TOT,DBLE(OUTG2(JG)))
DELTA=OUTG1(JG)*FI2TOT/(OUT2M*FI1TOT)-OUTG2(JG)/OUT2M
IF(IG.EQ.JG) SOUT1=SOUT1+ABS1(IBM,IG)*DELTA/OUT2M
SOUT2=SOUT2+(OUTG1(JG)/FI1TOT)*SUM(LHS1(IBM,:NG,IG))*
1 DELTA/OUT2M
ENDDO
GRAD(IPERT)=GRAD(IPERT)+2.0D0*WEI*FI2TOT*(SOUT1-SOUT2)/
1 FI1TOT/VARV(IPERT)
ENDIF
* equality constraints
GRAD(IPERT)=GRAD(IPERT)-2.0D0*CONST(IG-NGR1+1)*PHI2(IBM,IG)/
1 (DSUM*VARV(IPERT)**2)
ENDDO
IPERT=IPERT+NALBP
ENDDO
10 CALL LCMPUT(IPGRAD,'GRADIENT-DIR',NPERT,4,GRAD)
DEALLOCATE(GRAD)
*----
* SCRATCH STORAGE DEALLOCATION
*----
20 DEALLOCATE(VARV,SIGF,SIGA,OUTG2R,OUTG2,OUTG1,GAMMA,RHS,IREL,CONST,
1 LHS2,RHS2,LHS1,RHS1,ABS2,ABS1,PHI2,PHI1)
RETURN
*
100 FORMAT(/40H DREKOU: RMS ERROR ON RATE DISTRIBUTION=,1P,E11.4)
110 FORMAT(23H DREKOU: CONSTRAINT(,I4,2H)=,1P,E11.4)
120 FORMAT(5X,16HABSORPTION RATE(,I4,2H)=,1P,2E12.4)
130 FORMAT(5X,6HGROUP=,I4,9H LEAKAGE=,1P,2E12.4)
END
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