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*DECK ERRDRV
SUBROUTINE ERRDRV(IMPX,IPMAC1,IPMAC2,NREG,NREG2,NGRP,HREAC,ERAMAX,
1 ERASUM,ERQMAX,ERQSUM,ERGMARR,ERGSARR)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Perform reaction rate statistics between two extended macrolibs.
*
*Copyright:
* Copyright (C) 2002 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
* IPMAC1 pointer to the reference extended macrolib.
* IPMAC2 pointer to the approximate extended macrolib.
* NREG number of regions in the macrolib.
* NREG2 number of regions used for statistics.
* NGRP number of energy groups in the macrolib.
* HREAC nuclear reaction used to compute power map
*
*Parameters: output
* ERAMAX maximum relative error on absorption rates.
* ERASUM average relative error on absorption rates.
* ERQMAX maximum relative error on QUANDRY powers.
* ERQSUM average relative error on QUANDRY powers.
*
*-----------------------------------------------------------------------
*
USE GANLIB
*----
* SUBROUTINE ARGUMENTS
*----
TYPE(C_PTR) IPMAC1,IPMAC2
INTEGER IMPX,NREG,NGRP
REAL ERAMAX,ERASUM,ERQMAX,ERQSUM,ERGMARR(NGRP),ERGSARR(NGRP)
CHARACTER HREAC*8
*----
* LOCAL VARIABLES
*----
PARAMETER (NSTATE=40)
CHARACTER HSMG*131
INTEGER IDATA(NSTATE)
TYPE(C_PTR) JPMAC1,KPMAC1,JPMAC2,KPMAC2
REAL, DIMENSION(:), ALLOCATABLE :: VOL1,VOL2,TOTAL,GAR,FLUX,
1 QUAN1,QUAN2,TRABS1,TRABS2
REAL, DIMENSION(:,:), ALLOCATABLE :: TRA1,TRA2,XABS1,XABS2
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(TRA1(NREG2,NGRP),TRA2(NREG,NGRP),XABS1(NREG,NGRP),
1 XABS2(NREG,NGRP),VOL1(NREG),VOL2(NREG),TOTAL(NREG),GAR(NREG),
2 FLUX(NREG),QUAN1(NREG),QUAN2(NREG),TRABS1(NREG),TRABS2(NREG))
*----
* RECOVER REFERENCE REACTION RATES:
*----
CALL LCMGET(IPMAC1,'STATE-VECTOR',IDATA)
IF((NREG.NE.IDATA(2)).OR.(NGRP.NE.IDATA(1))) THEN
CALL XABORT('ERRDRV: INVALID VALUE OF NREG OR NGRP.')
ENDIF
CALL LCMGET(IPMAC1,'VOLUME',VOL1)
VOL1T=0.0
PWR1T=0.0
DO 10 I=1,NREG2
TRABS1(I)=0.0
QUAN1(I)=0.0
VOL1T=VOL1T+VOL1(I)
10 CONTINUE
TRA1(:NREG2,:NGRP)=0.0
CALL ERRABS(IPMAC1,NREG2,NREG,NGRP,XABS1)
JPMAC1=LCMGID(IPMAC1,'GROUP')
DO 35 IGR=1,NGRP
KPMAC1=LCMGIL(JPMAC1,IGR)
CALL LCMGET(KPMAC1,'NTOT0',TOTAL)
CALL LCMGET(KPMAC1,'SIGW00',GAR)
CALL LCMGET(KPMAC1,'FLUX-INTG',FLUX)
DO 20 I=1,NREG2
IF(VOL1(I).EQ.0.0) GO TO 20
TRA1(I,IGR)=(TOTAL(I)-GAR(I))*FLUX(I)/VOL1(I)
TRABS1(I)=TRABS1(I)+XABS1(I,IGR)*FLUX(I)/VOL1(I)
20 CONTINUE
CALL LCMLEN(KPMAC1,HREAC,ILONG,ITYLCM)
IF(ILONG.EQ.0) THEN
WRITE(HSMG,'(32HERRDRV: UNABLE TO FIND REACTION ,A,1H.)') HREAC
CALL XABORT(HSMG)
ENDIF
CALL LCMGET(KPMAC1,HREAC,GAR)
DO 30 I=1,NREG2
QUAN1(I)=QUAN1(I)+GAR(I)*FLUX(I)
PWR1T=PWR1T+QUAN1(I)
30 CONTINUE
35 CONTINUE
*----
* RECOVER APPROXIMATE REACTION RATES:
*----
CALL LCMGET(IPMAC2,'STATE-VECTOR',IDATA)
IF((NREG.NE.IDATA(2)).OR.(NGRP.NE.IDATA(1))) THEN
CALL XABORT('ERRDRV: INVALID VALUE OF NREG OR NGRP.')
ENDIF
CALL LCMGET(IPMAC2,'VOLUME',VOL2)
VOL2T=0.0
PWR2T=0.0
DO 50 I=1,NREG2
TRABS2(I)=0.0
QUAN2(I)=0.0
VOL2T=VOL2T+VOL2(I)
50 CONTINUE
CALL ERRABS(IPMAC2,NREG2,NREG,NGRP,XABS2)
JPMAC2=LCMGID(IPMAC2,'GROUP')
DO 80 IGR=1,NGRP
KPMAC2=LCMGIL(JPMAC2,IGR)
CALL LCMGET(KPMAC2,'NTOT0',TOTAL)
CALL LCMGET(KPMAC2,'SIGW00',GAR)
CALL LCMGET(KPMAC2,'FLUX-INTG',FLUX)
DO 60 I=1,NREG2
IF(VOL2(I).EQ.0.0) GO TO 60
TRA2(I,IGR)=(TOTAL(I)-GAR(I))*FLUX(I)/VOL2(I)
TRABS2(I)=TRABS2(I)+XABS2(I,IGR)*FLUX(I)/VOL2(I)
60 CONTINUE
IF(ILONG.NE.0) THEN
CALL LCMGET(KPMAC2,HREAC,GAR)
DO 70 I=1,NREG2
QUAN2(I)=QUAN2(I)+GAR(I)*FLUX(I)
PWR2T=PWR2T+QUAN2(I)
70 CONTINUE
ENDIF
80 CONTINUE
*----
* COMPUTE QUANDRY TYPE NORMALIZED POWER DENSITIES.
*----
IF(ILONG.GT.0) THEN
DO 90 I=1,NREG2
IF(VOL1(I).NE.0.0) QUAN1(I)=QUAN1(I)/VOL1(I)
IF(VOL2(I).NE.0.0) QUAN2(I)=QUAN2(I)/VOL2(I)
IF(PWR1T.NE.0.0) QUAN1(I)=QUAN1(I)*VOL1T/PWR1T
IF(PWR2T.NE.0.0) QUAN2(I)=QUAN2(I)*VOL2T/PWR2T
90 CONTINUE
ENDIF
*----
* PRINT STATISTICS ON GROUPWISE REMOVAL RATES.
*----
WRITE(6,'(/47H ERRDRV: STATISTICS ON GROUPWISE REMOVAL RATES:)')
SUMREF=0.0
SUM=0.0
DO 125 IGR=1,NGRP
DO 120 I=1,NREG2
SUMREF=SUMREF+TRA1(I,IGR)*VOL1(I)
SUM=SUM+TRA2(I,IGR)*VOL2(I)
120 CONTINUE
125 CONTINUE
DO 150 IGR=1,NGRP
WRITE (6,'(/17H PROCESSING GROUP,I3)') IGR
ERGMAX=0.0
ERGSUM=0.0
VOLTOT=0.0
DO 130 I=1,NREG2
TRA2(I,IGR)=TRA2(I,IGR)*(SUMREF/SUM)*(VOL2T/VOL1T)
IF(TRA1(I,IGR).NE.0.0) THEN
VOLTOT=VOLTOT+VOL1(I)
GAR(I)=100.0*(TRA2(I,IGR)-TRA1(I,IGR))/TRA1(I,IGR)
ELSE
GAR(I)=0.0
ENDIF
ERGSUM=ERGSUM+VOL1(I)*ABS(GAR(I))
ERGMAX=MAX(ERGMAX,ABS(GAR(I)))
130 CONTINUE
ERGSUM=ERGSUM/VOLTOT
ERGMARR(IGR)=ERGMAX
ERGSARR(IGR)=ERGSUM
IF(IMPX.GT.1) WRITE (6,'(/8X,9HREFERENCE,7X,6HAPPROX,7X,5HERROR)')
DO 140 I=1,NREG2
IF(IMPX.GT.1) WRITE (6,'(4X,I4,1X,1P,2E13.5,0P,F9.3,2H %)')
1 I,TRA1(I,IGR),TRA2(I,IGR),GAR(I)
140 CONTINUE
WRITE(6,300) IGR, ERGMAX,ERGMAX,ERGMAX
WRITE(6,310) IGR, ERGSUM,ERGSUM,ERGSUM
150 CONTINUE
WRITE(6,400) MAXVAL(ERGMARR), MAXVAL(ERGMARR),
1 MAXVAL(ERGMARR)
WRITE(6,410) MAXVAL(ERGSARR), MAXVAL(ERGSARR),
1 MAXVAL(ERGSARR)
*----
* PRINT STATISTICS ON CONDENSED ABSORPTION RATES.
*----
WRITE(6,'(/40H ERRDRV: STATISTICS ON ABSORPTION RATES:)')
SUMREF=0.0
SUM=0.0
DO 160 I=1,NREG2
SUMREF=SUMREF+TRABS1(I)*VOL1(I)
SUM=SUM+TRABS2(I)*VOL2(I)
160 CONTINUE
ERAMAX=0.0
ERASUM=0.0
VOLTOT=0.0
DO 165 I=1,NREG2
TRABS2(I)=TRABS2(I)*(SUMREF/SUM)*(VOL2T/VOL1T)
IF(TRABS1(I).NE.0.0) THEN
VOLTOT=VOLTOT+VOL1(I)
GAR(I)=100.0*(TRABS2(I)-TRABS1(I))/TRABS1(I)
ELSE
GAR(I)=0.0
ENDIF
ERASUM=ERASUM+VOL1(I)*ABS(GAR(I))
ERAMAX=MAX(ERAMAX,ABS(GAR(I)))
165 CONTINUE
ERASUM=ERASUM/VOLTOT
IF(IMPX.GT.1) WRITE (6,'(/8X,9HREFERENCE,7X,6HAPPROX,7X,5HERROR)')
DO 170 I=1,NREG2
IF(IMPX.GT.1) WRITE (6,'(4X,I4,1X,1P,2E13.5,0P,F9.3,2H %)')
1 I,TRABS1(I),TRABS2(I),GAR(I)
170 CONTINUE
WRITE(6,420) ERAMAX,ERAMAX,ERAMAX
WRITE(6,430) ERASUM,ERASUM,ERASUM
*----
* PRINT STATISTICS ON QUANDRY TYPE NORMALIZED POWER DENSITIES.
*----
IF(ILONG.NE.0) THEN
WRITE(6,'(/48H ERRDRV: STATISTICS ON QUANDRY TYPE NORMALIZED P,
1 15HOWER DENSITIES:)')
ERQMAX=0.0
ERQSUM=0.0
VOLTOT=0.0
DO 180 I=1,NREG2
ERR=ABS(VOL1(I)/VOL1T-VOL2(I)/VOL2T)
IF(ERR.GT.1.0E-4*ABS(VOL1(I)/VOL1T)) THEN
WRITE(HSMG,'(37HERRDRV: INCONSISTENT VOLUME IN REGION,I5,
1 3H BY,F7.2,2H %)') I,ERR*100.0
CALL XABORT(HSMG)
ENDIF
GAR(I)=0.0
IF(QUAN1(I).EQ.0.0) GO TO 180
VOLTOT=VOLTOT+VOL1(I)
GAR(I)=100.0*(QUAN2(I)-QUAN1(I))/QUAN1(I)
ERQSUM=ERQSUM+VOL1(I)*ABS(QUAN1(I)-QUAN2(I))/QUAN1(I)
ERQMAX=MAX(ERQMAX,ABS(GAR(I)))
180 CONTINUE
IF(VOLTOT.NE.0.0) ERQSUM=100.0*ERQSUM/VOLTOT
IF(IMPX.GT.1)
1 WRITE(6,'(/8X,9HREFERENCE,7X,6HAPPROX,7X,5HERROR)')
DO 190 I=1,NREG2
IF((QUAN1(I).NE.0.0).OR.(QUAN2(I).NE.0.0)) THEN
IF(IMPX.GT.1) WRITE(6,'(4X,I4,1X,1P,2E13.5,0P,F9.3,2H %)')
1 I,QUAN1(I),QUAN2(I),GAR(I)
ENDIF
190 CONTINUE
WRITE(6,440) ERQMAX,ERQMAX,ERQMAX
WRITE(6,450) ERQSUM,ERQSUM,ERQSUM
ENDIF
*----
* PRINT STATISTICS ON K-EFFECTIVE.
*----
CALL LCMLEN(IPMAC1,'K-EFFECTIVE',LENGT,ITYLCM)
IF(LENGT.EQ.1) THEN
CALL LCMGET(IPMAC1,'K-EFFECTIVE',FKEFF1)
CALL LCMGET(IPMAC2,'K-EFFECTIVE',FKEFF2)
WRITE(6,'(/5X,22HREFERENCE K-EFFECTIVE=,F9.6/8X,11HAPPROX K-EF,
1 8HFECTIVE=,F9.6,8H ERROR=,F9.1,4H PCM)') FKEFF1,FKEFF2,
2 (FKEFF2-FKEFF1)*1.0E5
ENDIF
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(XABS2,XABS1,TRA1,TRA2,VOL1,VOL2,TOTAL,GAR,FLUX,QUAN2,
1 QUAN1,TRABS2,TRABS1)
RETURN
*
300 FORMAT(/1X,37HGROUPWISE REM. RATE MAX ERR FOR GROUP,I4,2H =,
1 F9.3,2H %,F9.2,2H %,F9.1,2H %)
310 FORMAT( 1X,37HGROUPWISE REM. RATE AV. ERR FOR GROUP,I4,2H =,
1 F9.3,2H %,F9.2,2H %,F9.1,2H %/)
400 FORMAT(/1X,30HMAXIMUM ERROR OVER ALL GROUPS=,F9.3,2H %,F9.2,2H %,
1 F9.1,2H %)
410 FORMAT( 1X,30HAVERAGE ERROR OVER ALL GROUPS=,F9.3,2H %,F9.2,2H %,
1 F9.1,2H %/)
420 FORMAT(/1X,30HABSORPTION RATE MAXIMUM ERROR=,F9.3,2H %,F9.2,2H %,
1 F9.1,2H %)
430 FORMAT( 1X,30HABSORPTION RATE AVERAGE ERROR=,F9.3,2H %,F9.2,2H %,
1 F9.1,2H %/)
440 FORMAT(/1X,28HPOWER DENSITY MAXIMUM ERROR=,F9.3,2H %,F9.2,2H %,
1 F9.1,2H %)
450 FORMAT( 1X,28HPOWER DENSITY AVERAGE ERROR=,F9.3,2H %,F9.2,2H %,
1 F9.1,2H %/)
END
|
