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|
*DECK LIBFQD
SUBROUTINE LIBFQD(MAXNOR,LPART,MAXTRA,HNAMIS,IPLIB,NGRO,NL,NED,
1 NDEL,NDIL,IGRMIN,IGRMAX,LBIN,NFS,IMPX,LSCAT,LSIGF,LADD,DILUT,
2 FLUX,TOTAL,SIGF,SIGS,SCAT,SADD,ZDEL,EBIN,SIGTF,SIGSF,SIGFF,
3 AWR,ISMIN,ISMAX,GOLD,IPRECI,NOR,LBSIGF)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Compute NOR-point Calendf-type probability tables;
* compute physical and/or slowing-down correlated probability tables;
* component of the Ribon extended method.
*
*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 first dimension of matrix PRTSIG. Equal to the maximum order
* of a probability table.
* LPART maximum scattering bandwidth for the isotope.
* MAXTRA maximum number of energy bins of size DELI.
* HNAMIS name of the isotope.
* IPLIB pointer to the internal library (L_LIBRARY signature).
* NGRO number of energy groups.
* NL number of Legendre orders required in the calculation
* (NL=1 or higher).
* NED number of extra vector edits.
* NDEL number of delayed neutron precursor groups.
* NDIL number of finite dilutions.
* IGRMIN first self-shielded group with BIN data.
* IGRMAX most thermal self-shielded group with BIN data.
* LBIN number of fine (bin) energy groups.
* NFS number of fine energy groups in each group.
* IMPX print flag (equal to zero for no print).
* LSCAT anisotropy flag (=.true. if a given Legendre order of the
* scattering cross section exists).
* LSIGF fission flag (=.true. if the isotope can fission).
* LADD additional cross section flag (=.true. if a given additional
* cross section exists).
* DILUT dilutions.
* FLUX weighting flux.
* TOTAL total cross sections.
* SIGF nu*fission cross sections.
* SIGS scattering cross sections.
* SCAT scattering transfer matrices (sec,prim,Legendre,dilution).
* SADD additional cross sections.
* ZDEL delayed nu-sigf cross sections.
* EBIN fine group energy limits in EV.
* SIGTF microscopic total x-sections in the fine groups.
* SIGSF microscopic P0 scattering x-sections in the fine groups.
* AWR mass ratio for current isotope.
* SIGFF microscopic nu*fission cross sections in the fine groups.
* ISMIN minimum secondary group corresponding to each primary group.
* ISMAX maximum secondary group corresponding to each primary group.
* GOLD method flag: =-998.0 to use the CALENDF approach; =-999.0 to
* use the Ribon extended approach; =1.0 to use the ST model.
* IPRECI accuracy index for probability tables in CALENDF.
* LBSIGF autolib (bin) fission data flag.
*
*Parameters: output
* NOR number of subgroups in each group.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPLIB
INTEGER MAXNOR,LPART,MAXTRA,NGRO,NL,NED,NDEL,NDIL,IGRMIN,IGRMAX,
1 LBIN,NFS(NGRO),IMPX,ISMIN(NL,NGRO),ISMAX(NL,NGRO),IPRECI,
2 NOR(NGRO)
REAL DILUT(NDIL+1),FLUX(NGRO,NDIL+1),TOTAL(NGRO,NDIL+1),
1 SIGF(NGRO,NDIL+1),SIGS(NGRO,NL,NDIL+1),SCAT(NGRO,NGRO,NL,NDIL+1),
2 SADD(NGRO,NED,NDIL+1),ZDEL(NGRO,NDEL,NDIL+1),EBIN(LBIN+1),
3 SIGTF(LBIN),SIGSF(LBIN),SIGFF(LBIN),AWR,GOLD(NGRO)
LOGICAL LSCAT(NL),LSIGF,LADD(NED),LBSIGF
CHARACTER HNAMIS*12
*----
* LOCAL VARIABLES
*----
PARAMETER (IALTER=0,MAXDIL=65)
TYPE(C_PTR) JPLIB,KPLIB
CHARACTER HSMG*131,TAG*2
LOGICAL LNORAJ,LPHYS,LCALEN,LRIBON,LDIL(MAXDIL+1),LPTMC
INTEGER IPERD(MAXDIL+1)
REAL XSREF(MAXDIL),TEST(8),DILUT2(MAXDIL+1),TSCAT(20,MAXDIL),
1 DIFFS(20,MAXDIL)
DOUBLE PRECISION SIGTI2,SIGAI2,SIGTIN,SIGAIN,DELMAC,T,TF,T0,T1,
1 T2,ACCUM1,ACCUM2,ACCUM3,ACCUM4,FACT(MAXDIL),BB(MAXDIL+1)
*----
* ALLOCATABLE ARRAYS
*----
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: ISM
REAL, ALLOCATABLE, DIMENSION(:) :: WSLD,DELTA,UUU,STIS,SIGAF,
1 PRTSIW,PRTABS,GAR,SEFR
REAL, ALLOCATABLE, DIMENSION(:,:) :: PRTSIG,PRI,PRTSIG1,PRTSIG2,
1 SCAT00,PRTRS
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: PRTPH
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:) :: PHIMT,CC,MOMT,MOMP
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:) :: MATRIX,WORK,RSTAR
DOUBLE PRECISION, ALLOCATABLE, DIMENSION(:,:,:) :: PHI
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(ISM(2,NL))
ALLOCATE(PRTSIG(MAXNOR,3+NL+NL*LPART+NED+NDEL),WSLD(MAXNOR**2),
1 DELTA(LBIN),UUU(LBIN),STIS(LBIN),SIGAF(LBIN),
2 PRI(MAXTRA,NL),PRTPH(MAXNOR,NDIL,NL),PRTSIW(MAXNOR),
3 PRTABS(MAXNOR),PRTRS(MAXNOR,NDIL+1),
4 PRTSIG1(MAXNOR,3+NL+NL*LPART+NED+NDEL),SCAT00(LBIN,NGRO),
5 PRTSIG2(MAXNOR,3+NL+NL*LPART+NED+NDEL),GAR(LBIN))
ALLOCATE(PHIMT(MAXNOR),MATRIX(MAXNOR,MAXNOR+1),
1 PHI(LBIN,NDIL,NL),WORK(NDIL+1,MAXNOR),CC(MAXNOR),
2 RSTAR(LBIN,NDIL+1))
*
IF(NDIL.GT.MAXDIL) CALL XABORT('LIBFQD: MAXDIL OVERFLOW.')
*----
* NORMALIZE THE BIN-TYPE DATA AND COMPUTE DELTA AND SIGAF.
*----
IBIN=0
DELMIN=1.0E10
DO 40 IGRP=IGRMIN,IGRMAX
SIGTIN=0.0D0
SIGAIN=0.0D0
SIGSIN=0.0D0
SIGFIN=0.0D0
SIGTI2=0.0D0
SIGAI2=0.0D0
SIGSI2=0.0D0
SIGFI2=0.0D0
DO 20 IGF=1,NFS(IGRP)
DELM=LOG(EBIN(IBIN+IGF)/EBIN(IBIN+IGF+1))
DELMIN=MIN(DELMIN,DELM)
SIGTIN=SIGTIN+SIGTF(IBIN+IGF)*DELM
SIGAIN=SIGAIN+(SIGTF(IBIN+IGF)-SIGSF(IBIN+IGF))*DELM
SIGSIN=SIGSIN+SIGSF(IBIN+IGF)*DELM
IF(LBSIGF) SIGFIN=SIGFIN+SIGFF(IBIN+IGF)*DELM
SIGTF(IBIN+IGF)=MAX(0.002,SIGTF(IBIN+IGF))
SIGAF(IBIN+IGF)=SIGTF(IBIN+IGF)-SIGSF(IBIN+IGF)
SIGTI2=SIGTI2+SIGTF(IBIN+IGF)*DELM
SIGAI2=SIGAI2+SIGAF(IBIN+IGF)*DELM
SIGSI2=SIGSI2+SIGSF(IBIN+IGF)*DELM
IF(LBSIGF) SIGFI2=SIGFI2+SIGFF(IBIN+IGF)*DELM
UUU(IBIN+IGF)=LOG(EBIN(1)/EBIN(IBIN+IGF+1))
DELTA(IBIN+IGF)=DELM
20 CONTINUE
DO 30 IGF=1,NFS(IGRP)
SIGTF(IBIN+IGF)=SIGTF(IBIN+IGF)*REAL(SIGTIN/SIGTI2)
SIGSF(IBIN+IGF)=SIGSF(IBIN+IGF)*REAL(SIGSIN/SIGSI2)
IF(LBSIGF) SIGFF(IBIN+IGF)=SIGFF(IBIN+IGF)*(SIGFIN/SIGFI2)
SIGAF(IBIN+IGF)=SIGAF(IBIN+IGF)*REAL(SIGAIN/SIGAI2)
30 CONTINUE
IBIN=IBIN+NFS(IGRP)
40 CONTINUE
*----
* ASSUME THAT THE ELEMENTARY LETHARGY WIDTH DELI IS A RATIONAL FRACTION
* OF THE LETHARGY UNIT. CHECK THIS ASSUMPTION.
*----
CALL LCMLEN(IPLIB,'BIN-DELI',LENGT,ITYLCM)
IF((LENGT.EQ.1).AND.(ITYLCM.EQ.2)) THEN
CALL LCMGET(IPLIB,'BIN-DELI',DELI)
ELSE
DELI=1.0/REAL(INT(1.00001/DELMIN))
ENDIF
IBIN=0
ERR=0.0
DO 60 IGRP=IGRMIN,IGRMAX
DO 50 IGF=1,NFS(IGRP)
LARGH=INT(DELTA(IBIN+IGF)/DELI+0.1)
ERR=MAX(ERR,ABS(DELTA(IBIN+IGF)/DELI-REAL(LARGH)))
50 CONTINUE
IBIN=IBIN+NFS(IGRP)
60 CONTINUE
IF((IMPX.GT.0).OR.(ERR.GT.0.05)) THEN
WRITE(6,'(/47H LIBFQD: THE ELEMENTARY LETHARGY WIDTH OF ISOTO,
1 4HPE '',A12,11H'' IS SET TO,1P,E11.4,6H. ERR=,E10.3)') HNAMIS,
2 DELI,ERR
ENDIF
IF(ERR.GT.0.05) THEN
WRITE(HSMG,'(45HLIBFQD: UNABLE TO SET THE ELEMENTARY LETHARGY,
1 20H WIDTH FOR ISOTOPE '',A12,2H''.)') HNAMIS
WRITE(6,'(A)') HSMG
ENDIF
*----
* COMPUTE THE PRI ARRAY FOR VARIOUS LEGENDRE ORDERS.
*----
DO 70 IL=1,NL
CALL LIBPRI(MAXTRA,DELI,AWR,IALTER,IL-1,NEXT,PRI(1,IL))
70 CONTINUE
*----
* COMPUTE AUTOLIB CROSS SECTIONS FOR THE PO SCATTERING MATRIX
*----
SCAT00(:LBIN,:NGRO)=0.0
LLL=0
DO IGRP=IGRMIN,IGRMAX
GAR0=0.0
DO LI=1,NFS(IGRP)
LLL=LLL+1
GAR0=GAR0+DELTA(LLL)
GAR(:LBIN)=0.0
CALL LIBECT(MAXTRA,LLL,PRI(1,1),UUU,DELI,DELTA,NEXT,1,
1 MML,STIS)
DO I=1,MML
LLJ=LLL-I+1
GAR(LLJ)=STIS(I)*SIGSF(LLJ)*DELTA(LLJ)/DELTA(LLL)
ENDDO
LLJ=0
DO JGRP=IGRMIN,IGRMAX
DO LJ=1,NFS(JGRP)
LLJ=LLJ+1
SCAT00(LLJ,IGRP)=SCAT00(LLJ,IGRP)+GAR(LLJ)
ENDDO
ENDDO
ENDDO
ENDDO
*----
* MAIN LOOP OVER THE COARSE ENERGY GROUPS.
*----
NOR(:NGRO)=0
CALL LCMSIX(IPLIB,'PT-TABLE',1)
CALL LCMPUT(IPLIB,'NDEL',1,1,NDEL)
IBIN=0
JPLIB=LCMLID(IPLIB,'GROUP-PT',NGRO)
* ------------------
DO 810 IGRP=1,NGRO
*----
* REMOVE BADLY BEHAVED COLLOCATIONS POINTS.
*----
MDIL=NDIL
LDIL(:NDIL+1)=.TRUE.
DO 90 IDIL=NDIL,1,-1
IF(DILUT(IDIL).LT.1.0) THEN
MDIL=MDIL-1
LDIL(IDIL)=.FALSE.
ELSE IF((DILUT(IDIL).GT.1.0E5).AND.(DILUT(IDIL).LT.1.0E10)) THEN
MDIL=MDIL-1
LDIL(IDIL)=.FALSE.
ELSE IF(TOTAL(IGRP,IDIL).LE.0.0) THEN
MDIL=MDIL-1
LDIL(IDIL)=.FALSE.
ENDIF
90 CONTINUE
IDD=0
DO 100 IDIL=1,NDIL+1
IF(LDIL(IDIL)) THEN
IDD=IDD+1
DILUT2(IDD)=DILUT(IDIL)
IPERD(IDD)=IDIL
ENDIF
100 CONTINUE
IF(IDD.NE.MDIL+1) CALL XABORT('LIBFQD: INTERNAL ERROR.')
*
LCALEN=(NFS(IGRP).GT.0).AND.(GOLD(IGRP).EQ.-998.0)
LRIBON=(NFS(IGRP).GT.0).AND.(GOLD(IGRP).EQ.-999.0)
LPTMC=(NFS(IGRP).GT.0).AND.(GOLD(IGRP).EQ.-1000.0)
*----
* ACTIVE SPM IN GROUPS IGRMAX-1 and IGRMAX
*----
IF(LPTMC.AND.(IGRP.GE.IGRMAX-1)) THEN
LPTMC=.FALSE.
LCALEN=.TRUE.
ENDIF
LPHYS=(.NOT.LCALEN).AND.(.NOT.LRIBON).AND.(.NOT.LPTMC)
*
PRTSIG(:MAXNOR,:3+NL+NL*LPART+NED+NDEL)=0.0
*
IF(IMPX.GT.1) THEN
WRITE(6,'(/25H LIBFQD: PROCESSING GROUP,I4,14H FOR ISOTOPE '',
1 A12,2H''.)') IGRP,HNAMIS
ENDIF
DO 110 IDIL=1,MDIL
JDIL=IPERD(IDIL)
XSREF(IDIL)=TOTAL(IGRP,JDIL)-SIGS(IGRP,1,JDIL)
110 CONTINUE
*----
* COMPUTE THE RESONANT FLUX BY SOLVING A SLOWING-DOWN EQUATION. COMPUTE
* STIS USING LIBECT AND COMPUTE THE FINE FLUX. NORMALIZE THE RESONANT
* FLUX TO THE DILUTION-DEPENDENT NJOY COLLISION RATES.
*----
IF(LRIBON) THEN
RSTAR(:LBIN,:NDIL+1)=0.0D0
DO 142 IDIL=1,MDIL
T0=0.0D0
DELMAC=0.0D0
DO 130 IGF=1,NFS(IGRP)
DELM=DELTA(IBIN+IGF)
DELMAC=DELMAC+DELM
CALL LIBECT(MAXTRA,IBIN+IGF,PRI(1,1),UUU,DELI,DELTA,NEXT,1,
1 MML,STIS)
PHI(IBIN+IGF,IDIL,1)=DILUT2(IDIL)
DO 120 J=2,MML
JGF=IBIN+IGF-J+1
PHI(IBIN+IGF,IDIL,1)=PHI(IBIN+IGF,IDIL,1)+DBLE(STIS(J)*
1 (SIGTF(JGF)-SIGAF(JGF))*DELTA(JGF)/DELTA(IBIN+IGF))*
2 PHI(JGF,IDIL,1)
120 CONTINUE
PHI(IBIN+IGF,IDIL,1)=PHI(IBIN+IGF,IDIL,1)/(SIGTF(IBIN+IGF)+
1 DILUT2(IDIL)-DBLE(STIS(1)*(SIGTF(IBIN+IGF)-SIGAF(IBIN+IGF))))
T0=T0+PHI(IBIN+IGF,IDIL,1)*SIGTF(IBIN+IGF)*DELM
130 CONTINUE
*
JDIL=IPERD(IDIL)
FACT(IDIL)=FLUX(IGRP,JDIL)*TOTAL(IGRP,JDIL)*DELMAC/T0
DO 141 IL=2,NL
DO 140 IGF=1,NFS(IGRP)
BONDAR=SIGTF(IBIN+IGF)+DILUT2(IDIL)
PHI(IBIN+IGF,IDIL,IL)=PHI(IBIN+IGF,IDIL,IL-1)/BONDAR
140 CONTINUE
141 CONTINUE
142 CONTINUE
*
* COMPUTE THE FINE-GROUP SLOWING-DOWN SOURCE.
DO 152 IGF=1,NFS(IGRP)
CALL LIBECT(MAXTRA,IBIN+IGF,PRI(1,1),UUU,DELI,DELTA,NEXT,1,
1 MML,STIS)
DO 151 J=1,MML
JGF=IBIN+IGF-J+1
ACCUM1=DBLE(STIS(J)*(SIGTF(JGF)-SIGAF(JGF))*DELTA(JGF)/
1 DELTA(IBIN+IGF))
DO 150 IDIL=1,MDIL+1
IF(IDIL.LE.MDIL) THEN
RSTAR(IBIN+IGF,IDIL)=RSTAR(IBIN+IGF,IDIL)+ACCUM1*
1 PHI(JGF,IDIL,1)
ELSE
RSTAR(IBIN+IGF,IDIL)=RSTAR(IBIN+IGF,IDIL)+ACCUM1
ENDIF
150 CONTINUE
151 CONTINUE
152 CONTINUE
DO 162 IDIL=1,MDIL
DO 161 IGF=1,NFS(IGRP)
RSTAR(IBIN+IGF,IDIL)=RSTAR(IBIN+IGF,IDIL)*FACT(IDIL)
DO 160 IL=1,NL
PHI(IBIN+IGF,IDIL,IL)=PHI(IBIN+IGF,IDIL,IL)*FACT(IDIL)
160 CONTINUE
161 CONTINUE
162 CONTINUE
ENDIF
*----
* TEST FINE FLUX.
*----
IF((IMPX.GT.5).AND.LRIBON) THEN
WRITE(6,910) IGRP,HNAMIS
DO 240 IDIL=1,MDIL
DELMAC=0.0D0
TF=0.0D0
T0=0.0D0
T1=0.0D0
T2=0.0D0
DO 230 IGF=1,NFS(IGRP)
DELM=DELTA(IBIN+IGF)
DELMAC=DELMAC+DELM
TF=TF+PHI(IBIN+IGF,IDIL,1)*DELM
T0=T0+PHI(IBIN+IGF,IDIL,1)*SIGTF(IBIN+IGF)*DELM
T1=T1+PHI(IBIN+IGF,IDIL,1)*SIGAF(IBIN+IGF)*DELM
T2=T2+RSTAR(IBIN+IGF,IDIL)*DELM
230 CONTINUE
JDIL=IPERD(IDIL)
BTOT=TOTAL(IGRP,JDIL)*FLUX(IGRP,JDIL)
BABS=(TOTAL(IGRP,JDIL)-SIGS(IGRP,1,JDIL))*FLUX(IGRP,JDIL)
WRITE(6,'(1X,I5,1P,8E12.4)') IDIL,T0/DELMAC,BTOT,T1/DELMAC,
1 BABS,T2/DELMAC,(T0+DILUT2(IDIL)*TF)/DELMAC-DILUT2(IDIL),
2 TF/DELMAC,((T2/DELMAC)+DILUT2(IDIL))/((T0/TF)+DILUT2(IDIL))
240 CONTINUE
DELMAC=0.0D0
T0=0.0D0
T1=0.0D0
DO 250 IGF=1,NFS(IGRP)
DELM=DELTA(IBIN+IGF)
DELMAC=DELMAC+DELM
T0=T0+SIGTF(IBIN+IGF)*DELM
T1=T1+SIGAF(IBIN+IGF)*DELM
250 CONTINUE
BTOT=TOTAL(IGRP,NDIL+1)
BABS=TOTAL(IGRP,NDIL+1)-SIGS(IGRP,1,NDIL+1)
WRITE(6,'(3X,3HINF,1P,4E12.4)') T0/DELMAC,BTOT,T1/DELMAC,BABS
ENDIF
*----
* PROCESS CLASSICAL PROBABILITY TABLE INFORMATION IN TOTAL XS.
*----
LNORAJ=.TRUE.
ERROR1=0.0
260 NPAR=1
IF(LPHYS) THEN
NPART=3+NL+NED+NDEL
DO 270 IL=1,NL
NPART=NPART+MAX(ISMAX(IL,IGRP)-ISMIN(IL,IGRP)+1,0)
270 CONTINUE
IF(NPART.GT.3+NL+NL*LPART+NED+NDEL) CALL XABORT('LIBFQD: BUG.')
CALL LIBTAB (IGRP,NGRO,NL,NDIL,NPART,NED,NDEL,HNAMIS,IMPX,
1 LSCAT,LSIGF,LADD,DILUT,TOTAL,SIGF,SIGS,SCAT,SADD,ZDEL,1.0,
2 ISMIN,ISMAX,NOR(IGRP),PRTSIG)
DO 280 JNOR=1,NOR(IGRP)
PRTABS(JNOR)=PRTSIG(JNOR,2)-PRTSIG(JNOR,4)
280 CONTINUE
GO TO 780
ELSE IF(LCALEN.OR.LRIBON) THEN
ALLOCATE(MOMT(2*MAXNOR),MOMP(MAXNOR),SEFR((NPAR+2)*MDIL))
CALL LIBMOM(NFS(IGRP),MDIL,NPAR,DELTA(IBIN+1),SIGTF(IBIN+1),
1 SIGAF(IBIN+1),SIGTF(IBIN+1),MAXNOR,DILUT2,MOMT,
2 MOMP,SEFR)
*
CALL LIBCAT(MAXNOR,NPAR,MDIL,MOMT,MOMP,IPRECI,LNORAJ,DILUT2,
1 SEFR,NOR(IGRP),PRTSIG,ERRBST)
ERROR1=ERRBST
*
DEALLOCATE(SEFR,MOMP,MOMT)
DO 285 JNOR=1,NOR(IGRP)
PRTABS(JNOR)=PRTSIG(JNOR,3)! absorption
PRTSIG(JNOR,3)=0.0
285 CONTINUE
*---
ELSE IF(LPTMC) THEN
IF(LBSIGF) NPAR=2
ALLOCATE(MOMT(2*MAXNOR),MOMP(NPAR*MAXNOR),SEFR((NPAR+2)*MDIL))
* CALENDF PT FOR SIGT, SIGS AND NUSIGF
CALL LIBMOM(NFS(IGRP),MDIL,NPAR,DELTA(IBIN+1),SIGTF(IBIN+1),
1 SIGSF(IBIN+1),SIGFF(IBIN+1),MAXNOR,DILUT2,MOMT,MOMP,SEFR)
CALL LIBCAT(MAXNOR,NPAR,MDIL,MOMT,MOMP,IPRECI,LNORAJ,DILUT2,
1 SEFR,NOR(IGRP),PRTSIG1,ERRBST)
ERROR1=ERRBST
DEALLOCATE(SEFR,MOMP,MOMT)
*
DO INOR=1,NOR(IGRP)
PRTSIG(INOR,1)=PRTSIG1(INOR,1)!weight
PRTSIG(INOR,2)=PRTSIG1(INOR,2)!total
IF(LBSIGF) THEN
PRTSIG(INOR,3)=PRTSIG1(INOR,4)!fission
ELSE
PRTSIG(INOR,3)=0.0
ENDIF
PRTSIG(INOR,4)=PRTSIG1(INOR,3)!scattering
PRTABS(INOR)=PRTSIG(INOR,2)-PRTSIG(INOR,4)! absorption
ENDDO
*
IOF2=4+NL
DO IL=1,NL
DO JGRP=ISMIN(IL,IGRP),ISMAX(IL,IGRP)
NPAR2=1
ALLOCATE(MOMT(2*MAXNOR),MOMP(NPAR*MAXNOR),
1 SEFR((NPAR+2)*MDIL))
CALL LIBMOM(NFS(IGRP),MDIL,NPAR2,DELTA(IBIN+1),
1 SIGTF(IBIN+1),SCAT00(IBIN+1,JGRP),SIGTF(IBIN+1),MAXNOR,
2 DILUT2,MOMT,MOMP,SEFR)
LNORAJ=.FALSE.
CALL LIBCAT(MAXNOR,NPAR2,MDIL,MOMT,MOMP,IPRECI,LNORAJ,
1 DILUT2,SEFR,NOR(IGRP),PRTSIG2,ERRBST)
ERROR1=ERRBST
DEALLOCATE(SEFR,MOMP,MOMT)
DO INOR=1,NOR(IGRP)
PRTSIG(INOR,IOF2)=PRTSIG2(INOR,3)
ENDDO
IOF2=IOF2+1
ENDDO
ENDDO
NPAR=MAX(NPAR,NPAR2)
ENDIF
IF(NOR(IGRP).EQ.0) THEN
CALL XABORT('LIBFQD: NO SUBGROUPS.')
ELSE IF(NOR(IGRP).GT.MDIL) THEN
LNORAJ=.FALSE.
NOR(IGRP)=MDIL
GO TO 260
ENDIF
*----
* REMOVING SMALL PROBABILITIES.
*----
INOR=0
290 INOR=INOR+1
IF(INOR.GT.NOR(IGRP)) GO TO 310
IF(ABS(PRTSIG(INOR,1)).LT.1.0E-10) THEN
DO 305 JNOR=INOR+1,NOR(IGRP)
DO 300 J=1,NPAR+2
PRTSIG(JNOR-1,J)=PRTSIG(JNOR,J)
300 CONTINUE
305 CONTINUE
INOR=INOR-1
NOR(IGRP)=NOR(IGRP)-1
ENDIF
GO TO 290
*
310 IF(LRIBON.AND.(IMPX.GT.3)) THEN
WRITE(6,'(/7X,11HPROBABILITY,7X,5HTOTAL,2X,10HABSORPTION)')
TEST(:3)=0.0
DO 320 INOR=1,NOR(IGRP)
TEST(1)=TEST(1)+PRTSIG(INOR,1)
TEST(2)=TEST(2)+PRTSIG(INOR,1)*PRTSIG(INOR,2)
TEST(3)=TEST(3)+PRTSIG(INOR,1)*PRTSIG(INOR,3)
WRITE(6,'(1X,I5,1P,3E12.4)') INOR,(PRTSIG(INOR,J),J=1,3)
320 CONTINUE
WRITE(6,'(6H CHECK,1P,3E12.4)') (TEST(J),J=1,3)
TEST(:3)=0.0
DO 330 I=1,NFS(IGRP)
TEST(1)=TEST(1)+DELTA(IBIN+I)
TEST(2)=TEST(2)+SIGTF(IBIN+I)*DELTA(IBIN+I)
TEST(3)=TEST(3)+SIGAF(IBIN+I)*DELTA(IBIN+I)
330 CONTINUE
DO 340 J=2,3
TEST(J)=TEST(J)/TEST(1)
340 CONTINUE
TEST(1)=1.0
WRITE(6,'(6H EXACT,1P,3E12.4)') (TEST(J),J=1,3)
ENDIF
*----
* COMPUTE THE REFERENCE SELF-SHIELDED CROSS SECTIONS AT SELECTED
* VALUES OF THE DILUTION FOR AN HOMOGENEOUS MEDIA. SECOL-TYPE
* APPROXIMATION.
*----
IF(IBIN+NFS(IGRP).GT.LBIN) CALL XABORT('LIBFQD: PHI OVERFLOW.')
*
DO 405 IDIL=1,MDIL
DO 400 IL=1,NL
IF(LPHYS.OR.LCALEN.OR.LPTMC) THEN
* USE A BONDARENKO RESONANT FLUX.
T0=0.0D0
DO 350 INOR=1,NOR(IGRP)
BONDAR=(DILUT2(IDIL)+PRTSIG(INOR,2))**IL
PRTPH(INOR,IDIL,IL)=DILUT2(IDIL)/BONDAR
T0=T0+PRTSIG(INOR,1)*PRTPH(INOR,IDIL,1)
350 CONTINUE
IF(IL.EQ.1) BB(IDIL)=FLUX(IGRP,IPERD(IDIL))/T0
DO 360 INOR=1,NOR(IGRP)
PRTPH(INOR,IDIL,IL)=PRTPH(INOR,IDIL,IL)*REAL(BB(IDIL))
360 CONTINUE
ELSE
* COMPUTE THE BASE POINTS OF THE RESONANT FLUX.
JINI=(1-NOR(IGRP))/2
PHIMT(:NOR(IGRP))=0.0D0
DELMAC=0.0D0
DO 385 IGF=1,NFS(IGRP)
DELM=DELTA(IBIN+IGF)
SIGT=SIGTF(IBIN+IGF)
DELMAC=DELMAC+DELM
T0=PHI(IBIN+IGF,IDIL,IL)*DELM
T=T0
DO 370 INOR=1-JINI,NOR(IGRP)
PHIMT(INOR)=PHIMT(INOR)+T
T=T*SIGT
370 CONTINUE
T=T0/SIGT
DO 380 INOR=-JINI,1,-1
PHIMT(INOR)=PHIMT(INOR)+T
T=T/SIGT
380 CONTINUE
385 CONTINUE
DO 390 INOR=1,NOR(IGRP)
PHIMT(INOR)=PHIMT(INOR)/DELMAC
390 CONTINUE
CALL LIBMPA(NOR(IGRP),JINI,PRTSIG(1,1),PRTSIG(1,2),PHIMT,
1 PRTPH(1,IDIL,IL))
ENDIF
400 CONTINUE
405 CONTINUE
*----
* COMPUTE THE BASE POINTS OF THE SLOWING-DOWN SOURCE.
*----
IF(LRIBON) THEN
JINI=-NOR(IGRP)/2
DO 440 IDIL=1,MDIL+1
PHIMT(:NOR(IGRP))=0.0D0
DELMAC=0.0D0
DO 425 IGF=1,NFS(IGRP)
DELM=DELTA(IBIN+IGF)
SIGT=SIGTF(IBIN+IGF)
DELMAC=DELMAC+DELM
T0=RSTAR(IBIN+IGF,IDIL)*DELM
T=T0
DO 410 INOR=1-JINI,NOR(IGRP)
PHIMT(INOR)=PHIMT(INOR)+T
T=T*SIGT
410 CONTINUE
T=T0/SIGT
DO 420 INOR=-JINI,1,-1
PHIMT(INOR)=PHIMT(INOR)+T
T=T/SIGT
420 CONTINUE
425 CONTINUE
DO 430 INOR=1,NOR(IGRP)
PHIMT(INOR)=PHIMT(INOR)/DELMAC
430 CONTINUE
CALL LIBMPA(NOR(IGRP),JINI,PRTSIG(1,1),PRTSIG(1,2),PHIMT,
1 PRTRS(1,IDIL))
440 CONTINUE
ENDIF
*----
* NORMALIZATION OF THE FLUX-RELATED BASE POINTS. THIS NORMALIZATION
* PERMITS TO RE-OBTAIN THE BASE POINTS IN TOTAL X-SECTION IF THE RMS
* APPROACH IS APPLIED TO THE PRTPH MATRIX.
*----
DO 490 IDIL=1,MDIL
T0=0.0D0
DO 450 INOR=1,NOR(IGRP)
T0=T0+PRTSIG(INOR,1)*PRTSIG(INOR,2)*PRTPH(INOR,IDIL,1)
450 CONTINUE
JDIL=IPERD(IDIL)
FACTOR=FLUX(IGRP,JDIL)*TOTAL(IGRP,JDIL)/REAL(T0)
DO 465 IL=1,NL
DO 460 INOR=1,NOR(IGRP)
PRTPH(INOR,IDIL,IL)=PRTPH(INOR,IDIL,IL)*FACTOR
460 CONTINUE
465 CONTINUE
*
IF(IMPX.GT.9) THEN
WRITE(6,'(/7X,11HPROBABILITY,3X,9HFINE-FLUX,4X,9HDILUTION=,1P,
1 E8.1,5H BARN)') DILUT2(IDIL)
TEST(1)=0.0
TEST(2)=0.0
TEST(3)=0.0
DO 470 INOR=1,NOR(IGRP)
PGAR=PRTPH(INOR,IDIL,1)
TEST(1)=TEST(1)+PRTSIG(INOR,1)
TEST(2)=TEST(2)+PRTSIG(INOR,1)*PGAR
TEST(3)=TEST(3)+PRTSIG(INOR,1)*PRTSIG(INOR,2)*PGAR
WRITE(6,'(1X,I5,1P,2E12.4)') INOR,PRTSIG(INOR,1),PGAR
470 CONTINUE
TEST(3)=TEST(3)/TEST(2)
TEST(2)=TEST(2)/TEST(1)
WRITE(6,'(6H CHECK,1P,3E12.4)') (TEST(J),J=1,3)
IF(LRIBON) THEN
TEST(1)=0.0
TEST(2)=0.0
TEST(3)=0.0
DO 480 IGF=1,NFS(IGRP)
DELM=DELTA(IBIN+IGF)
TEST(1)=TEST(1)+DELM
TEST(2)=TEST(2)+REAL(PHI(IBIN+IGF,IDIL,1))*DELM
TEST(3)=TEST(3)+REAL(PHI(IBIN+IGF,IDIL,1))*SIGTF(IBIN+IGF)*
1 DELM
480 CONTINUE
TEST(3)=TEST(3)/TEST(2)
TEST(2)=TEST(2)/TEST(1)
TEST(1)=1.0
WRITE(6,'(6H EXACT,1P,3E12.4)') (TEST(J),J=1,3)
ENDIF
ENDIF
490 CONTINUE
*----
* USE A ROOT MEAN SQUARE TECHNIQUE TO FIND BASE POINTS OF THE
* SCATTERING XS VECTOR AND MATRIX CORRELATED TO THE TOTAL XS IN
* GROUP IGRP. NOTE: PRTPH(INOR,IDIL,1) IS USED INSTEAD OF
* PRTPH(INOR,IDIL,IL) ON LINE LABELED 500 IN ORDER TO BE CONSISTENT
* WITH USSIT0 AND USSIT1. THIS MAY CHANGE IN FUTURE.
*----
IF(LPTMC) GO TO 780
IOF1=4
IOF2=NL+4
DO 560 IL=1,NL
IF(LSCAT(IL)) THEN
DO 505 INOR=1,NOR(IGRP)
WORK(MDIL+1,INOR)=1.0D0
DO 500 IDIL=1,MDIL
WORK(IDIL,INOR)=PRTPH(INOR,IDIL,1)
500 CONTINUE
505 CONTINUE
CALL ALST2F(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT)
DO 510 IDIL=1,MDIL+1
JDIL=IPERD(IDIL)
BB(IDIL)=SIGS(IGRP,IL,JDIL)*FLUX(IGRP,JDIL)
510 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 520 INOR=1,NOR(IGRP)
PRTSIG(INOR,IOF1)=REAL(CC(INOR))/PRTSIG(INOR,1)
520 CONTINUE
DO 550 JGRP=ISMIN(IL,IGRP),ISMAX(IL,IGRP)
DO 530 IDIL=1,MDIL+1
JDIL=IPERD(IDIL)
BB(IDIL)=SCAT(JGRP,IGRP,IL,JDIL)*FLUX(IGRP,JDIL)
530 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 540 INOR=1,NOR(IGRP)
PRTSIG(INOR,IOF2)=REAL(CC(INOR))/PRTSIG(INOR,1)
540 CONTINUE
IOF2=IOF2+1
550 CONTINUE
ENDIF
IOF1=IOF1+1
560 CONTINUE
*----
* COMPUTE THE ROOT MEAN SQUARE COEFFICIENT MATRIX FOR P0 FLUX.
*----
DO 575 INOR=1,NOR(IGRP)
WORK(MDIL+1,INOR)=1.0D0
DO 570 IDIL=1,MDIL
WORK(IDIL,INOR)=PRTPH(INOR,IDIL,1)
570 CONTINUE
575 CONTINUE
CALL ALST2F(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT)
*----
* USE A ROOT MEAN SQUARE TECHNIQUE TO FIND BASE POINTS OF THE
* ABSORPTION XS CORRELATED TO THE TOTAL XS IN GROUP IGRP.
*----
DO 580 IDIL=1,MDIL+1
JDIL=IPERD(IDIL)
BB(IDIL)=(TOTAL(IGRP,JDIL)-SIGS(IGRP,1,JDIL))*FLUX(IGRP,JDIL)
580 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 590 INOR=1,NOR(IGRP)
PRTABS(INOR)=REAL(CC(INOR))/PRTSIG(INOR,1)
590 CONTINUE
*----
* USE A ROOT MEAN SQUARE TECHNIQUE TO FIND BASE POINTS OF THE NU*SIGF
* XS CORRELATED TO THE TOTAL XS IN GROUP IGRP.
*----
IF(LSIGF) THEN
DO 600 IDIL=1,MDIL+1
JDIL=IPERD(IDIL)
BB(IDIL)=SIGF(IGRP,JDIL)*FLUX(IGRP,JDIL)
600 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 610 INOR=1,NOR(IGRP)
PRTSIG(INOR,3)=REAL(CC(INOR))/PRTSIG(INOR,1)
610 CONTINUE
ENDIF
*----
* USE A ROOT MEAN SQUARE TECHNIQUE TO FIND BASE POINTS OF THE
* ADDITIONAL XS CORRELATED TO THE TOTAL XS IN GROUP IGRP.
*----
DO 640 IED=1,NED
IF(LADD(IED)) THEN
DO 620 IDIL=1,MDIL+1
JDIL=IPERD(IDIL)
BB(IDIL)=SADD(IGRP,IED,JDIL)*FLUX(IGRP,JDIL)
620 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 630 INOR=1,NOR(IGRP)
PRTSIG(INOR,IOF2)=REAL(CC(INOR))/PRTSIG(INOR,1)
630 CONTINUE
ENDIF
IOF2=IOF2+1
640 CONTINUE
*----
* USE A ROOT MEAN SQUARE TECHNIQUE TO FIND BASE POINTS OF THE DELAYED
* NU*SIGF XS CORRELATED TO THE TOTAL XS IN GROUP IGRP.
*----
IF(LSIGF) THEN
DO 670 IDEL=1,NDEL
DO 650 IDIL=1,MDIL+1
JDIL=IPERD(IDIL)
BB(IDIL)=ZDEL(IGRP,IDEL,JDIL)*FLUX(IGRP,JDIL)
650 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 660 INOR=1,NOR(IGRP)
PRTSIG(INOR,IOF2)=REAL(CC(INOR))/PRTSIG(INOR,1)
660 CONTINUE
IOF2=IOF2+1
670 CONTINUE
ENDIF
*----
* USE A ROOT MEAN SQUARE TECHNIQUE TO FIND THE ELEMENTS OF THE
* SLOWING-DOWN RELATED CORRELATED WEIGHT MATRIX AND SECONDARY
* SCATTERING XS IN GROUP IGRP.
*----
IF(LPHYS.OR.LCALEN.OR.LPTMC) THEN
DO 685 INOR=1,NOR(IGRP)
PRTSIW(INOR)=PRTSIG(INOR,4)
DO 680 JNOR=1,NOR(IGRP)
WSLD((INOR-1)*NOR(IGRP)+JNOR)=PRTSIG(INOR,1)*PRTSIG(JNOR,1)
680 CONTINUE
685 CONTINUE
ELSE
DO 705 INOR=1,NOR(IGRP)
DO 690 IDIL=1,MDIL+1
BB(IDIL)=PRTRS(INOR,IDIL)
690 CONTINUE
CALL ALST2S(NDIL+1,MDIL+1,NOR(IGRP),WORK,PHIMT,BB,CC)
DO 700 I=1,NOR(IGRP)
WSLD((I-1)*NOR(IGRP)+INOR)=REAL(CC(I))*PRTSIG(INOR,1)
700 CONTINUE
705 CONTINUE
*
DO 730 J=1,NOR(IGRP)
T0=0.0D0
DO 710 I=1,NOR(IGRP)
T0=T0+WSLD((J-1)*NOR(IGRP)+I)
710 CONTINUE
DO 720 I=1,NOR(IGRP)
WSLD((J-1)*NOR(IGRP)+I)=
1 REAL(WSLD((J-1)*NOR(IGRP)+I)*(PRTSIG(J,1)/T0))
720 CONTINUE
PRTSIW(J)=REAL(T0)/PRTSIG(J,1)
730 CONTINUE
ENDIF
IDOMAX=0
EROLD1=1.0E10
EROLD2=1.0E10
IF(LCALEN.OR.LPTMC) GO TO 780
*----
* SOLVE SUBGROUP FORM OF THE SLOWING-DOWN EQUATION FOR AN HOMOGENEOUS
* MIXTURE AT SELECTED DILUTIONS.
*----
ERROR1=-9999.0
ERROR2=-9999.0
IDMAX=0
DO 770 IDIL=1,MDIL
DO 750 I=1,NOR(IGRP)
MATRIX(I,NOR(IGRP)+1)=PRTSIG(I,1)*DILUT2(IDIL)
DO 740 J=1,NOR(IGRP)
MATRIX(I,J)=-WSLD((J-1)*NOR(IGRP)+I)*PRTSIW(J)
740 CONTINUE
MATRIX(I,I)=MATRIX(I,I)+(PRTSIG(I,2)+DILUT2(IDIL))*PRTSIG(I,1)
750 CONTINUE
CALL ALSBD(NOR(IGRP),1,MATRIX,IER,MAXNOR)
IF(IER.NE.0) CALL XABORT('LIBFQD: SINGULAR MATRIX(2).')
*----
* TEST THE ACCURACY OF THE PROBABILITY TABLES FOR THIS ENERGY GROUP.
*----
ACCUM1=0.0D0
ACCUM2=0.0D0
ACCUM3=0.0D0
ACCUM4=0.0D0
DO 760 I=1,NOR(IGRP)
ACCUM1=ACCUM1+PRTSIG(I,1)*PRTABS(I)*MATRIX(I,NOR(IGRP)+1)
ACCUM2=ACCUM2+PRTSIG(I,1)*MATRIX(I,NOR(IGRP)+1)
ACCUM3=ACCUM3+PRTSIG(I,1)*PRTABS(I)*PRTPH(I,IDIL,1)
ACCUM4=ACCUM4+PRTSIG(I,1)*PRTPH(I,IDIL,1)
760 CONTINUE
ACCUM1=ACCUM1/ACCUM2
ACCUM3=ACCUM3/ACCUM4
IF(ABS(ACCUM1-XSREF(IDIL))/ABS(XSREF(IDIL)).GT.ERROR1) THEN
EROLD1=ERROR1
EROLD2=ERROR2
IDOMAX=IDMAX
ERROR1=ABS(REAL(ACCUM1)-XSREF(IDIL))/ABS(XSREF(IDIL))
ERROR2=ABS(REAL(ACCUM3)-XSREF(IDIL))/ABS(XSREF(IDIL))
IDMAX=IDIL
ELSE IF(ABS(REAL(ACCUM1)-XSREF(IDIL))/ABS(XSREF(IDIL)).GT.EROLD1)
1 THEN
EROLD1=ABS(REAL(ACCUM1)-XSREF(IDIL))/ABS(XSREF(IDIL))
EROLD2=ABS(REAL(ACCUM3)-XSREF(IDIL))/ABS(XSREF(IDIL))
IDOMAX=IDIL
ENDIF
770 CONTINUE
IF(IMPX.GT.1) THEN
TAG='=>'
IF(LPHYS) TAG='--'
IF(LCALEN) TAG='=='
IF(LPTMC) TAG='>>'
WRITE(6,900) TAG,IGRP,NOR(IGRP),ERROR1*100.0,ERROR2*100.0,
1 DILUT2(IDMAX),EROLD1*100.0,EROLD2*100.0,DILUT2(IDOMAX)
ENDIF
IF(ERROR1.GT.0.01) THEN
WRITE(HSMG,'(42HLIBFQD: UNABLE TO COMPUTE THE PROBABILITY ,
1 15HTABLES IN GROUP,I4,17H. TABLE ACCURACY=,1P,E9.2,2H %,
2 10H ISOTOPE='',A12,2H''.)') IGRP,ERROR1*100.0,HNAMIS
WRITE(6,'(1X,A)') HSMG
ENDIF
*
780 IF((IMPX.GT.2).AND.(NOR(IGRP).GT.1)) THEN
WRITE(6,'(/7H GROUP=,I4,16H TABLE ACCURACY=,1P,E9.2,2H %)')
1 IGRP,ERROR1*100.0
WRITE(6,'(/7X,11HPROBABILITY,7X,5HTOTAL,2X,10HABSORPTION,2X,
1 10HNU-FISSION,2X,10HSCATTERING,12(1H.))')
TEST(:8)=0.0
IOF=NL+IGRP-ISMIN(1,IGRP)
JMIN=5
JMAX=MIN(JMIN+ISMAX(1,IGRP)-ISMIN(1,IGRP),8)
DO 790 JNOR=1,NOR(IGRP)
TEST(1)=TEST(1)+PRTSIG(JNOR,1)
TEST(2)=TEST(2)+PRTSIG(JNOR,1)*PRTSIG(JNOR,2)
TEST(3)=TEST(3)+PRTSIG(JNOR,1)*PRTABS(JNOR)
TEST(4)=TEST(4)+PRTSIG(JNOR,1)*PRTSIG(JNOR,3)
DO J=JMIN,JMAX
TEST(J)=TEST(J)+PRTSIG(JNOR,1)*PRTSIG(JNOR,IOF+J-1)
ENDDO
WRITE(6,'(1X,I5,1P,8E12.4)') JNOR,(PRTSIG(JNOR,J),J=1,2),
1 PRTABS(JNOR),PRTSIG(JNOR,3),(PRTSIG(JNOR,IOF+J-1),J=JMIN,JMAX)
790 CONTINUE
WRITE(6,'(6H CHECK,1P,8E12.4)') (TEST(J),J=1,JMAX)
TEST(:8)=0.0
TEST(1)=1.0
TEST(2)=TOTAL(IGRP,NDIL+1)
TEST(3)=TOTAL(IGRP,NDIL+1)-SIGS(IGRP,1,NDIL+1)
TEST(4)=SIGF(IGRP,NDIL+1)
DO J=JMIN,JMAX
TEST(J)=SCAT(IGRP+J-5,IGRP,1,NDIL+1)
ENDDO
WRITE(6,'(6H EXACT,1P,8E12.4)') (TEST(I),I=1,JMAX)
TEST(:8)=0.0
*---
* CHECK POINT BASES OF THE SCATTERING MATRIX
*---
IF(IGRP.GE.IGRMIN.AND.IGRP.LT.IGRMAX) THEN
DIFFS(:20,:MAXDIL)=0.0
DO IPART=4+NL,4+NL+ISMAX(1,IGRP)-ISMIN(1,IGRP)
DO IDIL=1,NDIL+1
TEST(:8)=0.0
DO INOR=1,NOR(IGRP)
TEST(1)=TEST(1)+PRTSIG(INOR,1)*PRTSIG(INOR,IPART)/
1 (PRTSIG(INOR,2)+DILUT2(IDIL))
TEST(2)=TEST(2)+PRTSIG(INOR,1)/(PRTSIG(INOR,2)+DILUT2(IDIL))
ENDDO
TSCAT(IPART,IDIL)=TEST(1)/TEST(2)
DIFFS(IPART,IDIL)=(TSCAT(IPART,IDIL)-
1 SCAT(IGRP+IPART-4-NL,IGRP,1,IDIL))/
2 SCAT(IGRP+IPART-4-NL,IGRP,1,IDIL)
ENDDO
WRITE(6,*)'SCATTERING MATRIX COEFFICIENTS FOR IDIL=1,NDIL+1'
WRITE(6,'(11H SECONDARY ,1P,I3,9H PRIMARY ,1P,I3)')
1 IGRP+IPART-4-NL,IGRP
WRITE(6,*)'CALENDF'
WRITE(6,'(5(4X,F12.4))') (TSCAT(IPART,IDIL),IDIL=1,NDIL+1)
WRITE(6,*)'NJOY'
WRITE(6,'(5(4X,F12.4))') (SCAT(IGRP+IPART-4-NL,
1 IGRP,1,IDIL),IDIL=1,NDIL+1)
WRITE(*,*)'RELATIVE DIFFERENCE (%)'
WRITE(6,'(5(4X,F12.4))')
1 (1.E2*DIFFS(IPART,IDIL),IDIL=1,NDIL+1)
ENDDO
ENDIF
ENDIF
IF(NOR(IGRP).GT.1) THEN
* SAVE THE PROBABILITY TABLE INTO IPLIB.
KPLIB=LCMDIL(JPLIB,IGRP)
NPART=3+NL+NED+NDEL
DO 800 IL=1,NL
ISM(1,IL)=ISMIN(IL,IGRP)
ISM(2,IL)=ISMAX(IL,IGRP)
NPART=NPART+MAX(0,(ISMAX(IL,IGRP)-ISMIN(IL,IGRP)+1))
800 CONTINUE
CALL LCMPUT(KPLIB,'PROB-TABLE',NPART*MAXNOR,2,PRTSIG)
IF(LRIBON) THEN
CALL LCMPUT(KPLIB,'SIGQT-SIGS',NOR(IGRP),2,PRTSIW)
CALL LCMPUT(KPLIB,'SIGQT-SLOW',NOR(IGRP)**2,2,WSLD)
ELSE IF(LCALEN.OR.LPTMC) THEN
IOF=NL+IGRP-ISMIN(1,IGRP)
CALL LCMPUT(KPLIB,'SIGQT-SIGS',NOR(IGRP),2,PRTSIG(1,IOF+4))
ENDIF
CALL LCMPUT(KPLIB,'ISM-LIMITS',2*NL,1,ISM)
ENDIF
IBIN=IBIN+NFS(IGRP)
810 CONTINUE
CALL LCMPUT(IPLIB,'NOR',NGRO,1,NOR)
CALL LCMSIX(IPLIB,' ',2)
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(RSTAR,CC,WORK,PHI,MATRIX,PHIMT)
DEALLOCATE(GAR,PRTSIG2,SCAT00,PRTSIG1,PRTRS,PRTABS,PRTSIW,PRTPH,
1 PRI,SIGAF,STIS,UUU,DELTA,WSLD,PRTSIG)
DEALLOCATE(ISM)
RETURN
*
900 FORMAT(/9H LIBFQD: ,A2,6HGROUP=,I3,7H ORDER=,I2,7H ERROR=,1P,
1 E9.2,4H % (,E9.2,15H %) AT DILUTION,E10.3,5H BARN/29X,
2 7H ERROR=,1P,E9.2,4H % (,E9.2,15H %) AT DILUTION,E10.3,6H BARN.)
910 FORMAT(/32H LIBFQD: TEST FINE FLUX IN GROUP,I5,14H FOR ISOTOPE ',
1 A12,2H':/9H DILUTION,16X,5HTOTAL,14X,10HABSORPTION,12X,
2 12HSLOWING-DOWN,20X,4HFLUX/11X,7HAUTOLIB,8X,4HNJOY,5X,7HAUTOLIB,
3 8X,4HNJOY)
END
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