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|
*DECK PCRONE
SUBROUTINE PCRONE(IMPX,ICAL,IPMIC,NCAL,NGRP,XS_CALC)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Copy an elementary calculation of the PMAXS file into a microlib.
*
*Copyright:
* Copyright (C) 2019 Ecole Polytechnique de Montreal
*
*Author(s):
* A. Hebert and D. Calic
*
*Parameters: input
* IMPX print parameter.
* ICAL index of the elementary calculation.
* IPMIC address of the microlib.
* NCAL number of elementary calculations in the PMAXS file.
* NGRP number of energy groups.
* XS_CALC pointers towards PMAXS elementary calculations.
*
*-----------------------------------------------------------------------
*
USE GANLIB
USE PCRDATA
*----
* SUBROUTINE ARGUMENTS
*----
INTEGER IMPX,ICAL,NCAL,NGRP
TYPE(C_PTR) IPMIC
TYPE(XSBLOCK_ITEM),TARGET :: XS_CALC(NCAL)
*----
* LOCAL VARIABLES
*----
TYPE(C_PTR) JPMIC,KPMIC
INTEGER NSTATE
PARAMETER(NSTATE=40)
INTEGER ISTATE(NSTATE),ITYPR(1)
REAL DENS(3)
DOUBLE PRECISION DELTA
LOGICAL LEX
CHARACTER(LEN=8) :: HVECT(3)
CHARACTER(LEN=12) :: HNAME,HISONA(3)
CHARACTER(LEN=131) :: HSMG
TYPE(XSBLOCK_TYPE),POINTER :: XSONE,XSREF
TYPE(TH_INDEP_VAR),POINTER :: TIVONE
*----
* ALLOCATABLE ARRAYS
*----
REAL, ALLOCATABLE, DIMENSION(:) :: SIG1,GAR,ENERGY
REAL, ALLOCATABLE, DIMENSION(:,:) :: SIG2
*----
* SET SIGNATURE AND STATE VECTOR
*----
INQUIRE(FILE='PCRONE.txt',EXIST=LEX)
IF(LEX) THEN
NUNIT=KDROPN('PCRONE.txt',1,3,0)
ELSE
NUNIT=KDROPN('PCRONE.txt',0,3,0)
ENDIF
IF(NUNIT.LE.0) THEN
WRITE(HSMG,'(28HPCRONE: KDROPN FAILURE (IER=,I5,2H).)') NUNIT
CALL XABORT(HSMG)
ENDIF
NED=1
HVECT(1)='H-FACTOR'
IF(NXST.GE.7) THEN
NED=2
HVECT(2)='NFTOT'
ENDIF
IF(NXST.EQ.8) THEN
NED=3
HVECT(3)='DETEC'
ENDIF
NBISO=1 ! number of isotopes
IF(NXST.GT.4) NBISO=3 ! include Xe and Sm
HNAME='L_LIBRARY'
CALL LCMPTC(IPMIC,'SIGNATURE',12,HNAME)
ISTATE(:)=0
ISTATE(1)=1
ISTATE(2)=NBISO
ISTATE(3)=NGRP
ISTATE(4)=1 ! isotropic scattering
ISTATE(13)=NED ! number of additional edits
ISTATE(19)=NDLAY ! number of delayed neutron groups
CALL LCMPUT(IPMIC,'STATE-VECTOR',NSTATE,1,ISTATE)
CALL LCMPTC(IPMIC,'ADDXSNAME-P0',8,NED,HVECT)
JPMIC=LCMLID(IPMIC,'ISOTOPESLIST',NBISO)
*
ALLOCATE(SIG1(NGRP),SIG2(NGRP,NGRP))
XSONE=>XS_CALC(ICAL)%XS
XSREF=>XS_CALC(XS_CALC(ICAL)%IBURN)%XS
WRITE(NUNIT,*)XS_CALC(ICAL)%IBURN
TIVONE=>XS_CALC(ICAL)%TIV
KPMIC=LCMDIL(JPMIC,1) ! step up isot 1
HISONA(1)='*MAC*RES'
DENS(1)=1.0
CALL LCMPTC(KPMIC,'ALIAS',12,HISONA(1))
*----
* PROCESS VECTORIAL CROSS SECTIONS
*----
* 1 2 3 4 5 6 7
* xtr,xab,xnf,xkf,xfi,xxe,xsm
*----
* RUN ELEMENTARY CALC IN CASE THE PMAXS FILE IS GIVEN AS DERIVATIVES
*----
IF(derivatives) THEN
DELTA=XS_CALC(ICAL)%DELTA
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,1)+DELTA*XSONE%sig(IG,1))
ENDDO
CALL LCMPUT(KPMIC,'STRD',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,2)+SUM(XSREF%sct(IG,:))+DELTA*
1 XSONE%sig(IG,2)+SUM(XSONE%sct(IG,:)))
ENDDO
CALL LCMPUT(KPMIC,'NTOT0',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,3)+DELTA*XSONE%sig(IG,3))
WRITE(NUNIT,*)SIG1(IG)
ENDDO
CALL LCMPUT(KPMIC,'NUSIGF',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,4)+DELTA*XSONE%sig(IG,4))
ENDDO
CALL LCMPUT(KPMIC,'H-FACTOR',NGRP,2,SIG1)
IF(NXST.GT.4) THEN
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,7)+DELTA*XSONE%sig(IG,7))
ENDDO
CALL LCMPUT(KPMIC,'NFTOT',NGRP,2,SIG1)
SIG1(:NGRP)=0.0
SIG1(1)=1.0
CALL LCMPUT(KPMIC,'CHI',NGRP,2,SIG1)
ENDIF
IF(NXST.EQ.8) THEN
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,8)+DELTA*XSONE%sig(IG,8))
ENDDO
CALL LCMPUT(KPMIC,'DETEC',NGRP,2,SIG1)
ENDIF
IF(lamb) THEN
ALLOCATE(GAR(ELAM-BLAM+1))
GAR(:ELAM-BLAM+1)=REAL(TIVONE%kinp(BLAM:ELAM))
CALL LCMPUT(KPMIC,'LAMBDA',ELAM-BLAM+1,2,GAR)
DEALLOCATE(GAR)
ENDIF
DO j=1,iXSTI
k=iTIV(j)
IF(k.GT.0) THEN
DO IG=1,NGRP
SIG1(IG)=REAL(TIVONE%sig(IG,k))
ENDDO
IF(j.EQ.1) THEN
CALL LCMPUT(KPMIC,'CHI',NGRP,2,SIG1)
ELSE IF(j.EQ.2) THEN
CALL LCMPUT(KPMIC,'CHID',NGRP,2,SIG1)
ELSE IF(j.EQ.3) THEN
CALL LCMPUT(KPMIC,'INVEL',NGRP,2,SIG1)
ENDIF
ENDIF
ENDDO
*----
* PROCESS SCATTERING INFORMATION (JG --> IG)
*----
DO IG=1,NGRP
SIG1(IG)=REAL(SUM(XSREF%sct(IG,:))+DELTA*SUM(XSONE%sct(IG,:)))
DO JG=1,NGRP
SIG2(IG,JG)=REAL(XSREF%sct(JG,IG)+DELTA*XSONE%sct(JG,IG))
ENDDO
ENDDO
ITYPR(1)=1
CALL XDRLGS(KPMIC,1,IMPX,0,0,1,NGRP,SIG1,SIG2,ITYPR)
IF(IMPX.GT.5) CALL LCMLIB(KPMIC)
*----
* PROCESS Xe and Sm
*----
IF(NXST.GT.4) THEN
KPMIC=LCMDIL(JPMIC,2) ! step up isot 2
HISONA(2)='Xe135'
DENS(2)=0.0
CALL LCMPTC(KPMIC,'ALIAS',12,HISONA(2))
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,5)+DELTA*XSONE%sig(IG,5))
ENDDO
CALL LCMPUT(KPMIC,'NTOT0',NGRP,2,SIG1)
CALL LCMPUT(KPMIC,'STRD',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=0.0
DO JG=1,NGRP
SIG2(IG,JG)=0.0
ENDDO
ENDDO
ITYPR(1)=1
CALL XDRLGS(KPMIC,1,IMPX,0,0,1,NGRP,SIG1,SIG2,ITYPR)
KPMIC=LCMDIL(JPMIC,3) ! step up isot 3
HISONA(3)='Sm149'
DENS(3)=0.0
CALL LCMPTC(KPMIC,'ALIAS',12,HISONA(3))
DO IG=1,NGRP
SIG1(IG)=REAL(XSREF%sig(IG,6)+DELTA*XSONE%sig(IG,6))
ENDDO
CALL LCMPUT(KPMIC,'NTOT0',NGRP,2,SIG1)
CALL LCMPUT(KPMIC,'STRD',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=0.0
DO JG=1,NGRP
SIG2(IG,JG)=0.0
ENDDO
ENDDO
ITYPR(1)=1
CALL XDRLGS(KPMIC,1,IMPX,0,0,1,NGRP,SIG1,SIG2,ITYPR)
ENDIF
CALL LCMPTC(IPMIC,'ISOTOPESUSED',12,NBISO,HISONA)
CALL LCMPUT(IPMIC,'ISOTOPESDENS',NBISO,2,DENS)
DEALLOCATE(SIG2,SIG1)
ELSE
*----
* RUN ELEMENTARY CALC IN CASE THE PMAXS FILE IS GIVEN AS RAW CROSS
* SECTIONS
*----
DELTA=XS_CALC(ICAL)%DELTA
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,1))
ENDDO
CALL LCMPUT(KPMIC,'STRD',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,2)+SUM(XSONE%sct(IG,:)))
ENDDO
CALL LCMPUT(KPMIC,'NTOT0',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,3))
WRITE(NUNIT,*)XSONE%sig(IG,3)
ENDDO
CALL LCMPUT(KPMIC,'NUSIGF',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,4))
ENDDO
CALL LCMPUT(KPMIC,'H-FACTOR',NGRP,2,SIG1)
IF(NXST.GT.4) THEN
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,7))
ENDDO
CALL LCMPUT(KPMIC,'NFTOT',NGRP,2,SIG1)
SIG1(:NGRP)=0.0
SIG1(1)=1.0
CALL LCMPUT(KPMIC,'CHI',NGRP,2,SIG1)
ENDIF
IF(NXST.EQ.8) THEN
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,8))
ENDDO
CALL LCMPUT(KPMIC,'DETEC',NGRP,2,SIG1)
ENDIF
IF(lamb) THEN
ALLOCATE(GAR(ELAM-BLAM+1))
GAR(:ELAM-BLAM+1)=REAL(TIVONE%kinp(BLAM:ELAM))
CALL LCMPUT(KPMIC,'LAMBDA',ELAM-BLAM+1,2,GAR)
DEALLOCATE(GAR)
ENDIF
DO j=1,iXSTI
k=iTIV(j)
IF(k.GT.0) THEN
DO IG=1,NGRP
SIG1(IG)=REAL(TIVONE%sig(IG,k))
ENDDO
IF(j.EQ.1) THEN
CALL LCMPUT(KPMIC,'CHI',NGRP,2,SIG1)
ELSE IF(j.EQ.2) THEN
CALL LCMPUT(KPMIC,'CHID',NGRP,2,SIG1)
ELSE IF(j.EQ.3) THEN
CALL LCMPUT(KPMIC,'INVEL',NGRP,2,SIG1)
ENDIF
ENDIF
ENDDO
*----
* PROCESS SCATTERING INFORMATION
*----
DO IG=1,NGRP
SIG1(IG)=REAL(SUM(XSONE%sct(IG,:)))
DO JG=1,NGRP
SIG2(IG,JG)=REAL(XSONE%sct(JG,IG)) ! JG --> IG
ENDDO
ENDDO
ITYPR(1)=1
CALL XDRLGS(KPMIC,1,IMPX,0,0,1,NGRP,SIG1,SIG2,ITYPR)
IF(IMPX.GT.5) CALL LCMLIB(KPMIC)
*----
* PROCESS Xe and Sm
*----
IF(NXST.GT.4) THEN
KPMIC=LCMDIL(JPMIC,2) ! step up isot 2
HISONA(2)='Xe135'
DENS(2)=0.0
CALL LCMPTC(KPMIC,'ALIAS',12,HISONA(2))
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,5))
ENDDO
CALL LCMPUT(KPMIC,'NTOT0',NGRP,2,SIG1)
CALL LCMPUT(KPMIC,'STRD',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=0.0
DO JG=1,NGRP
SIG2(IG,JG)=0.0
ENDDO
ENDDO
ITYPR(1)=1
CALL XDRLGS(KPMIC,1,IMPX,0,0,1,NGRP,SIG1,SIG2,ITYPR)
KPMIC=LCMDIL(JPMIC,3) ! step up isot 3
HISONA(3)='Sm149'
DENS(3)=0.0
CALL LCMPTC(KPMIC,'ALIAS',12,HISONA(3))
DO IG=1,NGRP
SIG1(IG)=REAL(XSONE%sig(IG,6))
ENDDO
CALL LCMPUT(KPMIC,'NTOT0',NGRP,2,SIG1)
CALL LCMPUT(KPMIC,'STRD',NGRP,2,SIG1)
DO IG=1,NGRP
SIG1(IG)=0.0
DO JG=1,NGRP
SIG2(IG,JG)=0.0
ENDDO
ENDDO
ITYPR(1)=1
CALL XDRLGS(KPMIC,1,IMPX,0,0,1,NGRP,SIG1,SIG2,ITYPR)
ENDIF
CALL LCMPTC(IPMIC,'ISOTOPESUSED',12,NBISO,HISONA)
CALL LCMPUT(IPMIC,'ISOTOPESDENS',NBISO,2,DENS)
DEALLOCATE(SIG2,SIG1)
ENDIF
CLOSE(NUNIT)
*----
* SET ENERGY MESH
*----
ALLOCATE(ENERGY(NGRP+1))
IF(NGRP.EQ.2) THEN
ENERGY(:)=(/ 1.964E7, 6.25E-1, 1.1E-4 /)
ELSE
CALL XABORT('PCRONE: UNKNOWN ENERGY MESH')
ENDIF
CALL LCMPUT(IPMIC,'ENERGY',NGRP+1,2,ENERGY)
DEALLOCATE(ENERGY)
RETURN
END
|
