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|
*DECK FMTSUD
SUBROUTINE FMTSUD(NENTRY,IENTRY,KENTRY,IPRINT,NOPT,IOPT,IKFLU,
> NREG ,NGROUP,NDIM ,POLOAQ,AZMOAQ,
> VOLUME,XPOL ,WPOL ,XAZI ,WAZI ,
> FLUX ,AFLUX ,TFLUX ,WGHT ,MU ,ETA )
*
*-----------------------------------------------------------------------
*
*Purpose:
* To process the angular fluxes and generate the SUS3D file.
*
*Copyright:
* Copyright (C) 2008 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):
* G. Marleau
*
*Parameters: input
* NENTRY number of data structures transfered to this module.
* IENTRY data structure type where:
* =1 for LCM memory object;
* =2 for XSM file;
* =3 for sequential binary file;
* =4 for sequential ASCII file.
* KENTRY data structure pointer.
* IPRINT print level.
* NOPT number of options.
* IOPT processing option.
* IKFLU pointer to the FLUX data structure.
* NREG number of regions for problem.
* NGROUP number of groups for problem.
* NDIM number of dimensions of problem.
* POLOAQ polar quadrature order.
* AZMOAQ azimuthal quadrature order.
* VOLUME regional volumes.
* XPOL polar quadrature points.
* WPOL polar quadrature weights.
* XAZI azimuthal quadrature points.
* WAZI azimuthal quadrature weights.
*
*Parameters: output
* FLUX direct and adjoint flux.
* AFLUX angular components of the direct and adjoint flux.
* TFLUX temporary flux vector.
* WGHT temporary weight.
* MU temporary mu.
* ETA temporary eta.
*
*----------
*
USE GANLIB
IMPLICIT NONE
*----
* Subroutine arguments
*----
TYPE(C_PTR) KENTRY(NENTRY)
INTEGER NENTRY,IENTRY(NENTRY)
INTEGER IPRINT,NOPT,IOPT(NOPT),IKFLU
INTEGER NREG,NGROUP,NDIM,POLOAQ,AZMOAQ
REAL VOLUME(NREG),XPOL(POLOAQ,2),WPOL(POLOAQ),
> XAZI(NDIM,AZMOAQ),WAZI(AZMOAQ)
REAL FLUX(NREG,2,NGROUP,2)
DOUBLE PRECISION AFLUX(NREG,POLOAQ,AZMOAQ*2,2,NGROUP)
DOUBLE PRECISION TFLUX(NREG+1,POLOAQ,AZMOAQ*2)
REAL WGHT(POLOAQ*AZMOAQ*2),MU(POLOAQ*AZMOAQ*2),
> ETA(POLOAQ*AZMOAQ*2)
*----
* Local parameters
*----
INTEGER IOUT
CHARACTER NAMSBR*6
PARAMETER (IOUT=6,NAMSBR='FMTSUD')
INTEGER ILCMUP,ILCMDN
PARAMETER (ILCMUP=1,ILCMDN=2)
*----
* Local variables
*----
TYPE(C_PTR) IPU
INTEGER IFPU,IAPU,IFORM,IGROUP,IKU,IAKU,NAZ,IA,IP,IR,IQUA
CHARACTER*12 NAMREC
REAL RELERR,ERRMAX,ETATMP,FNORM
*----
* Initialize FLUX vectors
*----
NAZ=AZMOAQ
DO IP=1,POLOAQ
XPOL(IP,2)=SQRT(1.-XPOL(IP,1)*XPOL(IP,1))
ENDDO
IF(IPRINT .GE. 10) THEN
WRITE(IOUT,6000) NAMSBR,NGROUP,NDIM,2*AZMOAQ,POLOAQ,NREG
WRITE(IOUT,6001)
WRITE(IOUT,6011)
> (XAZI(1,IA),XAZI(2,IA),WAZI(IA),IA=1,AZMOAQ)
WRITE(IOUT,6002)
WRITE(IOUT,6011)
> (XPOL(IP,1),XPOL(IP,2),WPOL(IP),IP=1,POLOAQ)
ENDIF
FLUX(:NREG,:2,:NGROUP,:2)=0.0
AFLUX(:NREG,:POLOAQ,:AZMOAQ*2,:2,:NGROUP)=0.0D0
*----
* Get information from FLUX data structure.
* 1. Flux
* 2. Angular flux
* 3. Adjoint
* 4. Angular adjoint
*----
IPU=KENTRY(IKFLU)
CALL LCMSIX(IPU,'FLUXDIRECT ',ILCMUP)
DO IGROUP=1,NGROUP
WRITE(NAMREC,'(A4,I3,5X)') 'FLUX',IGROUP
CALL LCMGET(IPU,NAMREC,FLUX(1,1,IGROUP,1))
ENDDO
CALL LCMSIX(IPU,'ANGULAR DIR ',ILCMUP)
DO IGROUP=1,NGROUP
WRITE(NAMREC,'(A5,I3,4X)') 'AFLUX',IGROUP
CALL LCMGET(IPU,NAMREC,AFLUX(1,1,1,1,IGROUP))
ENDDO
CALL LCMSIX(IPU,'ANGULAR DIR ',ILCMDN)
CALL LCMSIX(IPU,'FLUXDIRECT ',ILCMDN)
CALL LCMSIX(IPU,'FLUXADJOINT ',ILCMUP)
DO IGROUP=1,NGROUP
WRITE(NAMREC,'(A4,I3,5X)') 'FLUX',IGROUP
CALL LCMGET(IPU,NAMREC,FLUX(1,2,IGROUP,1))
ENDDO
CALL LCMSIX(IPU,'ANGULAR ADJ ',ILCMUP)
DO IGROUP=1,NGROUP
WRITE(NAMREC,'(A5,I3,4X)') 'AFLUX',IGROUP
CALL LCMGET(IPU,NAMREC,AFLUX(1,1,1,2,IGROUP))
ENDDO
CALL LCMSIX(IPU,'ANGULAR ADJ ',ILCMDN)
CALL LCMSIX(IPU,'FLUXADJOINT ',ILCMDN)
*----
* Create first SUS file
* Volume, and tracking directions
*----
IFPU=FILUNIT(KENTRY(1))
WRITE(IFPU,1000) NREG
WRITE(IFPU,1001) 2*AZMOAQ*POLOAQ
*----
* -\Omega (\varphi+\pi,\pi-\theta)
*----
IQUA=0
DO IA=1,AZMOAQ
ETATMP=XAZI(2,NAZ+1-IA)
IF(ETATMP .EQ. 0.0) THEN
ETATMP=1.0E-10
ENDIF
DO IP=1,POLOAQ
IQUA=IQUA+1
MU(IQUA)=-XPOL(IP,2)*XAZI(1,NAZ+1-IA)
ETA(IQUA)=-XPOL(IP,2)*ETATMP
WGHT(IQUA)=WPOL(IP)/WAZI(NAZ+1-IA)
ENDDO
ENDDO
*----
* +\Omega (\varphi,\theta)
*----
DO IA=1,AZMOAQ
ETATMP=XAZI(2,IA)
IF(ETATMP .EQ. 0.0) THEN
ETATMP=1.0E-10
ENDIF
DO IP=1,POLOAQ
IQUA=IQUA+1
MU(IQUA)=XPOL(IP,2)*XAZI(1,IA)
ETA(IQUA)=XPOL(IP,2)*ETATMP
WGHT(IQUA)=WPOL(IP)/WAZI(IA)
ENDDO
ENDDO
WRITE(IFPU,1010) 'wght',
> (WGHT(IQUA),IQUA=1,POLOAQ*AZMOAQ*2)
WRITE(IFPU,1010) 'mu ',
> (MU(IQUA),IQUA=1,POLOAQ*AZMOAQ*2)
WRITE(IFPU,1010) 'eta ',
> (ETA(IQUA),IQUA=1,POLOAQ*AZMOAQ*2)
WRITE(IFPU,1010) 'vol ',
> (VOLUME(IR),IR=1,NREG)
*----
* Print angular flux
*----
IFPU=FILUNIT(KENTRY(2))
IKU=IENTRY(2)
IFORM=IOPT(2)
ERRMAX=0.0
IF(IKU .EQ. 3) THEN
DO IGROUP=1,NGROUP
WRITE(IFPU) 'Group',IGROUP
ENDDO
DO IGROUP=NGROUP+1,NGROUP+6
WRITE(IFPU) 'Comments'
ENDDO
ELSE
DO IGROUP=1,NGROUP
WRITE(IFPU,'(A8,4X,I8)') 'Groups =',IGROUP
ENDDO
DO IGROUP=NGROUP+1,NGROUP+6
WRITE(IFPU,'(A8)') 'Comments'
ENDDO
ENDIF
DO IGROUP=1,NGROUP
DO IA=1,AZMOAQ*2
DO IP=1,POLOAQ
IF(IFORM .EQ. 1) THEN
DO IR=1,NREG
TFLUX(IR,IP,IA)=AFLUX(IR,IP,IA,1,IGROUP)
IF(IA .LE. AZMOAQ) THEN
FLUX(IR,1,IGROUP,2)=FLUX(IR,1,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,1,IGROUP)*WPOL(IP)/WAZI(NAZ+1-IA))
ELSE
FLUX(IR,1,IGROUP,2)=FLUX(IR,1,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,1,IGROUP)*WPOL(IP)/WAZI(IA-NAZ))
ENDIF
ENDDO
IF(IPRINT .GE. 100) THEN
WRITE(IOUT,6003) IP,IA,IGROUP
WRITE(IOUT,6010) (TFLUX(IR,IP,IA),IR=1,NREG)
ENDIF
ELSE
IR=1
TFLUX(IR,IP,IA)=AFLUX(IR,IP,IA,1,IGROUP)
DO IR=1,NREG
TFLUX(IR+1,IP,IA)=
> 2.0D0*AFLUX(IR,IP,IA,1,IGROUP)-TFLUX(IR,IP,IA)
IF(IA .LE. AZMOAQ) THEN
FLUX(IR,1,IGROUP,2)=FLUX(IR,1,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,1,IGROUP)*WPOL(IP)/WAZI(NAZ+1-IA))
ELSE
FLUX(IR,1,IGROUP,2)=FLUX(IR,1,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,1,IGROUP)*WPOL(IP)/WAZI(IA-NAZ))
ENDIF
ENDDO
IF(IPRINT .GE. 100) THEN
WRITE(IOUT,6003) IP,IA,IGROUP
WRITE(IOUT,6010)
> ((TFLUX(IR,IP,IA)+TFLUX(IR+1,IP,IA))/2.0,IR=1,NREG)
ENDIF
ENDIF
ENDDO
ENDDO
IF(IFORM .EQ. 1) THEN
IF(IKU .EQ. 3) THEN
WRITE(IFPU) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IFPU) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ELSE
WRITE(IFPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IFPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ENDIF
ELSE
IF(IKU .EQ. 3) THEN
WRITE(IFPU) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IFPU) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ELSE
WRITE(IFPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IFPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ENDIF
ENDIF
ENDDO
IF(IPRINT .GE. 10) THEN
FNORM=FLUX(1,1,1,2)/FLUX(1,1,1,1)
DO IGROUP=1,NGROUP
WRITE(6,6030) IGROUP
DO IR=1,NREG
RELERR=100.0*(FLUX(IR,1,IGROUP,2)
> -FNORM*FLUX(IR,1,IGROUP,1))
> /FLUX(IR,1,IGROUP,2)
ERRMAX=MAX(ERRMAX,ABS(RELERR))
IF(IPRINT .GE. 20) THEN
WRITE(6,6031) IR,FNORM*FLUX(IR,1,IGROUP,1),
> FLUX(IR,1,IGROUP,2),RELERR
ENDIF
ENDDO
ENDDO
WRITE(6,6020) ERRMAX
ENDIF
*----
* Print angular adjoint
*----
IAPU=FILUNIT(KENTRY(3))
IAKU=IENTRY(3)
ERRMAX=0.0
IF(IAKU .EQ. 3) THEN
DO IGROUP=NGROUP,1,-1
WRITE(IAPU) 'Group',IGROUP
ENDDO
DO IGROUP=NGROUP+1,NGROUP+6
WRITE(IAPU) 'Comments'
ENDDO
ELSE
DO IGROUP=NGROUP,1,-1
WRITE(IAPU,'(A8,4X,I8)') 'Groups =',IGROUP
ENDDO
DO IGROUP=NGROUP+1,NGROUP+6
WRITE(IAPU,'(A8)') 'Comments'
ENDDO
ENDIF
DO IGROUP=NGROUP,1,-1
DO IA=1,AZMOAQ*2
DO IP=1,POLOAQ
IF(IFORM .EQ. 1) THEN
DO IR=1,NREG
TFLUX(IR,IP,IA)=AFLUX(IR,IP,IA,2,IGROUP)
IF(IA .LE. AZMOAQ) THEN
FLUX(IR,2,IGROUP,2)=FLUX(IR,2,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,2,IGROUP)*WPOL(IP)/WAZI(NAZ+1-IA))
ELSE
FLUX(IR,2,IGROUP,2)=FLUX(IR,2,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,2,IGROUP)*WPOL(IP)/WAZI(IA-NAZ))
ENDIF
ENDDO
IF(IPRINT .GE. 100) THEN
WRITE(IOUT,6004) IP,IA,IGROUP
WRITE(IOUT,6010) (TFLUX(IR,IP,IA),IR=1,NREG)
ENDIF
ELSE
IR=1
TFLUX(IR,IP,IA)=AFLUX(IR,IP,IA,2,IGROUP)
DO IR=1,NREG
TFLUX(IR+1,IP,IA)=
> 2.0D0*AFLUX(IR,IP,IA,2,IGROUP)-TFLUX(IR,IP,IA)
IF(IA .LE. AZMOAQ) THEN
FLUX(IR,2,IGROUP,2)=FLUX(IR,2,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,2,IGROUP)*WPOL(IP)/WAZI(NAZ+1-IA))
ELSE
FLUX(IR,2,IGROUP,2)=FLUX(IR,2,IGROUP,2)
> +REAL(AFLUX(IR,IP,IA,2,IGROUP)*WPOL(IP)/WAZI(IA-NAZ))
ENDIF
ENDDO
IF(IPRINT .GE. 100) THEN
WRITE(IOUT,6004) IP,IA,IGROUP
WRITE(IOUT,6010)
> ((TFLUX(IR,IP,IA)+TFLUX(IR+1,IP,IA))/2.0,IR=1,NREG)
ENDIF
ENDIF
ENDDO
ENDDO
IF(IFORM .EQ. 1) THEN
IF(IAKU .EQ. 3) THEN
WRITE(IAPU) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IAPU) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ELSE
WRITE(IAPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IAPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ENDIF
ELSE
IF(IAKU .EQ. 3) THEN
WRITE(IAPU) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IAPU) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ELSE
WRITE(IAPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=1,AZMOAQ)
WRITE(IAPU,1002) (((TFLUX(IR,IP,IA),IR=1,NREG+1),
> IP=1,POLOAQ),IA=AZMOAQ*2,AZMOAQ+1,-1)
ENDIF
ENDIF
ENDDO
IF(IPRINT .GE. 10) THEN
FNORM=FLUX(1,2,1,2)/FLUX(1,2,1,1)
DO IGROUP=NGROUP,1,-1
WRITE(6,6032) IGROUP
DO IR=1,NREG
RELERR=100.0*(FLUX(IR,2,IGROUP,2)
> -FNORM*FLUX(IR,2,IGROUP,1))
> /FLUX(IR,1,IGROUP,2)
ERRMAX=MAX(ERRMAX,ABS(RELERR))
IF(IPRINT .GE. 20) THEN
WRITE(6,6031) IR,FNORM*FLUX(IR,2,IGROUP,1),
> FLUX(IR,2,IGROUP,2),RELERR
ENDIF
ENDDO
ENDDO
WRITE(6,6020) ERRMAX
ENDIF
*----
* Processing finished, return
*----
RETURN
*----
* Formats
*----
1000 FORMAT('Number of regions =',I5)
1001 FORMAT('Nomber of angles =',I5)
1002 FORMAT(1P,5E20.10)
1010 FORMAT(A4,1P/(3E15.7))
6000 FORMAT('Output from routine ',A6/
> 'Number of groups =',I5/
> 'Number of dimens =',I5/
> 'Number of azimuth =',I5/
> 'Number of polar =',I5/
> 'Number of regions =',I5)
6001 FORMAT('Azimuthal quadrature')
6002 FORMAT('Polar quadrature')
6003 FORMAT('Polar =',I5,2X,'Azim = ',I5,2X,'Group = ',I5/
> 'Direct angular flux per region ')
6004 FORMAT('Polar =',I5,2X,'Azim = ',I5,2X,'Group = ',I5/
> 'Adjoint angular flux per region')
6010 FORMAT(1P,5E20.10)
6011 FORMAT(1P,3E20.10)
6020 FORMAT('Maximum relative on flux (%) = ',F15.7)
6030 FORMAT(' Flux for group ',I5)
6031 FORMAT(' Region ',I5,1P,2E20.10,5X,0P,F20.10)
6032 FORMAT(' Adjoint for group ',I5)
END
|
