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*DECK SYB7QG
SUBROUTINE SYB7QG (IMPX,NCURR,MNA4,NRD,NSECT,LSECT,NREG,ZZR,ZZI,
1 HSIDE,RAYRE,SIGTR,TRONC,VOL,PIJ,PVS,PSS)
*
*-----------------------------------------------------------------------
*
*Purpose:
* Compute the one-group collision, leakage and transmission
* probabilities in a hexagonal sectorized cell.
*
*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
* IMPX print parameter (equal to zero for no print).
* NCURR type of interface current approximation:
* =1 DP-0; =3 DP-1 interface currents.
* MNA4 number of angles in (0,$\\pi$/2).
* NRD one plus the number of tubes in the cell.
* NSECT number of sectors.
* LSECT type of sectorization:
* =-999 no sectorization / processed as a sectorized cell;
* =-101 X-type sectorization of the coolant;
* =-1 X-type sectorization of the cell.
* NREG number of regions.
* ZZR real tracking elements.
* ZZI integer tracking elements.
* HSIDE length of the hexagon sides.
* RAYRE radius of the tubes.
* SIGTR total macroscopic cross section.
* TRONC voided block criterion.
*
*Parameters: output
* VOL volumes.
* PIJ volume to volume reduced probability.
* PVS volume to surface probabilities.
* PSS surface to surface probabilities in the following order:
* PSS(i,j) is the probability from surface i to surface j.
*
*Comments:
* hexagone surface identification.
* side 2
* xxxxxxxx
* x x
* side 3 x x side 1
* x x
* x x
* side 4 x x side 6
* xxxxxxxx
* side 5
*
*----
* SUBROUTINE ARGUMENTS
*----
INTEGER IMPX,NCURR,MNA4,NRD,NSECT,LSECT,NREG,ZZI(*)
REAL ZZR(*),HSIDE,RAYRE(NRD-1),SIGTR(NREG),TRONC,VOL(NREG),
1 PIJ(NREG,NREG),PVS(NREG,6*NCURR),PSS(6*NCURR,6*NCURR)
*----
* LOCAL VARIABLES
*----
PARAMETER (SIGVID=1.0E-10,NSURFQ=6)
INTEGER IPER(3)
REAL QSS(135)
INTEGER, ALLOCATABLE, DIMENSION(:,:) :: NUMREG
REAL, ALLOCATABLE, DIMENSION(:) :: VOLINT,WORKIJ,G
REAL, ALLOCATABLE, DIMENSION(:,:,:) :: PSIX
LOGICAL, ALLOCATABLE, DIMENSION(:) :: LGFULL
*----
* DATA STATEMENT AND INLINE FUNCTIONS
*----
SAVE IPER
DATA IPER/1,3,2/
INC(IC,IH)=(IC-1)*NCURR+IPER(IH)
INQ(IH,JH,IS)=(IS-1)*NCURR*NCURR+(IH-1)*NCURR+JH
*----
* SCRATCH STORAGE ALLOCATION
*----
ALLOCATE(NUMREG(NSECT,NRD))
ALLOCATE(VOLINT(NRD),WORKIJ(0:(NREG+6)*(NREG+7)/2-1),
1 PSIX(0:5,NCURR,NREG),G(NREG+6))
ALLOCATE(LGFULL(NREG))
*----
* COMPUTE THE VOLUMES
*----
CALL SYB7VO(NRD,HSIDE,RAYRE,VOLINT)
IND=0
DO 30 I=1,NRD-1
IF(ABS(LSECT).GT.100) THEN
IND=IND+1
DO 10 ISEC=1,NSECT
NUMREG(ISEC,I)=IND
10 CONTINUE
ELSE IF(LSECT.EQ.-1) THEN
NUMREG(1,I)=IND+5
NUMREG(2,I)=IND+6
NUMREG(3,I)=IND+1
NUMREG(4,I)=IND+2
NUMREG(5,I)=IND+3
NUMREG(6,I)=IND+4
IND=IND+6
ELSE
DO 20 ISEC=1,NSECT
IND=IND+1
NUMREG(ISEC,I)=IND
20 CONTINUE
ENDIF
30 CONTINUE
IF(LSECT.EQ.-999) THEN
IND=IND+1
DO 40 ISEC=1,NSECT
NUMREG(ISEC,I)=IND
40 CONTINUE
ELSE IF((LSECT.EQ.-1).OR.(LSECT.EQ.-101)) THEN
NUMREG(1,I)=IND+5
NUMREG(2,I)=IND+6
NUMREG(3,I)=IND+1
NUMREG(4,I)=IND+2
NUMREG(5,I)=IND+3
NUMREG(6,I)=IND+4
IND=IND+6
ELSE
DO 50 ISEC=1,NSECT
IND=IND+1
NUMREG(ISEC,I)=IND
50 CONTINUE
ENDIF
DO 60 I=1,NREG
VOL(I)=0.0
60 CONTINUE
DO 75 IR=1,NRD
DO 70 IS=1,NSECT
IND=NUMREG(IS,IR)
VOL(IND)=VOL(IND)+VOLINT(IR)/6.0
70 CONTINUE
75 CONTINUE
*----
* CHECK FOR VOIDED REGIONS
*----
DO 80 IR=1,NREG
IF(VOL(IR) .GT. 0.) THEN
DR=SQRT(VOL(IR))
ELSE
DR=0.0
ENDIF
LGFULL(IR)=(SIGTR(IR)*DR).GT.TRONC
IF(SIGTR(IR).LE.SIGVID) SIGTR(IR)=SIGVID
80 CONTINUE
*----
* COMPUTE COLLISION, DP-0 ESCAPE AND DP-0 TRANSMISSION PROBABILITIES
*----
MZIS=ZZI(1)
MZRS=ZZI(2)
CALL SYBUQV(ZZR(MZRS),ZZI(MZIS),NSURFQ,NREG,SIGTR,MNA4,LGFULL,
1 WORKIJ)
*----
* STAMM'LER RENORMALIZATION
*----
DO 90 IR=1,NSURFQ
G(IR)=HSIDE/4.0
90 CONTINUE
DO 100 IR=1,NREG
G(6+IR)=SIGTR(IR)*VOL(IR)
100 CONTINUE
* FIRST APPLY THE ORTHONORMALIZATION FACTOR:
DO 110 I=0,(NSURFQ+NREG)*(NSURFQ+NREG+1)/2-1
WORKIJ(I)=WORKIJ(I)*ZZR(MZRS)*ZZR(MZRS)
110 CONTINUE
*
* THEN PERFORM STAMM'LER NORMALIZATION:
CALL SYBRHL(IMPX,NSURFQ,NREG,G,WORKIJ)
*
IIJ=NSURFQ*(NSURFQ+1)/2-1
DO 130 JR=1,NREG
IIJ=IIJ+NSURFQ
DO 120 IR=1,JR-1
AUX=WORKIJ(IIJ+IR)/(SIGTR(IR)*SIGTR(JR))
PIJ(IR,JR)=AUX/VOL(IR)
PIJ(JR,IR)=AUX/VOL(JR)
120 CONTINUE
IIJ=IIJ+JR
AUX=WORKIJ(IIJ)/(SIGTR(JR)*SIGTR(JR))
PIJ(JR,JR)=AUX/VOL(JR)
130 CONTINUE
*----
* PIS AND PSS CALCULATION
*----
IF(NCURR.GT.1) THEN
* PERFORM A DP-1 CALCULATION USING THE TRACKING.
CALL SYBUQ0(ZZR(MZRS),ZZI(MZIS),NSURFQ,NREG,SIGTR,MNA4,
1 LGFULL,PSIX(0,1,1),QSS)
*
DO 160 JS=0,NSURFQ-1
DO 150 IH=1,NCURR
DO 140 IR=1,NREG
ZNOR=G(JS+1)+G(NSURFQ+IR)
PSIX(JS,IH,IR)=ZNOR*PSIX(JS,IH,IR)/SIGTR(IR)/VOL(IR)
140 CONTINUE
150 CONTINUE
160 CONTINUE
IIQ=1
DO 190 JS=0,NSURFQ-1
DO 180 IS=0,JS-1
ZNOR=G(IS+1)+G(JS+1)
DO 170 IH=1,NCURR*NCURR
QSS(IIQ)=ZNOR*QSS(IIQ)
IIQ=IIQ+1
170 CONTINUE
180 CONTINUE
190 CONTINUE
DO 210 IIQ=1,135,9
DO 200 IIS=1,8,2
QSS(IIQ+IIS)=-QSS(IIQ+IIS)
200 CONTINUE
210 CONTINUE
ELSE
* RECOVER PSI AND PSS INFORMATION FROM DP-0 PIJ CALCULATION.
IIQ=1
IIJ=0
DO 230 JS=0,NSURFQ-1
DO 220 IS=0,JS-1
QSS(IIQ)=4.0*WORKIJ(IIJ)
IIQ=IIQ+NCURR*NCURR
IIJ=IIJ+1
220 CONTINUE
IIJ=IIJ+1
230 CONTINUE
IIJ=NSURFQ*(NSURFQ+1)/2
DO 250 IR=1,NREG
DO 240 JS=0,NSURFQ-1
PSIX(JS,1,IR)=WORKIJ(IIJ+JS)/SIGTR(IR)/VOL(IR)
240 CONTINUE
IIJ=IIJ+NSURFQ+IR
250 CONTINUE
ENDIF
*----
* LOAD THE EURYDICE CP ARRAYS
*----
DO 270 I=1,NREG
DO 260 IH=1,NCURR
SGN=1.0
IF(IH.EQ.2) SGN=-1.0
PVS(I,INC(1,IH))=SGN*PSIX(2,IH,I)
PVS(I,INC(2,IH))=SGN*PSIX(3,IH,I)
PVS(I,INC(3,IH))=SGN*PSIX(4,IH,I)
PVS(I,INC(4,IH))=SGN*PSIX(5,IH,I)
PVS(I,INC(5,IH))=SGN*PSIX(0,IH,I)
PVS(I,INC(6,IH))=SGN*PSIX(1,IH,I)
260 CONTINUE
270 CONTINUE
DO 290 I=1,6*NCURR
DO 280 J=1,6*NCURR
PSS(I,J)=0.0
280 CONTINUE
290 CONTINUE
DO 310 IH=1,NCURR
DO 300 JH=1,NCURR
PSS(INC(2,IH),INC(1,JH))=QSS(INQ(IH,JH,6))/HSIDE
PSS(INC(3,IH),INC(1,JH))=QSS(INQ(IH,JH,9))/HSIDE
PSS(INC(4,IH),INC(1,JH))=QSS(INQ(JH,IH,13))/HSIDE
PSS(INC(5,IH),INC(1,JH))=QSS(INQ(JH,IH,2))/HSIDE
PSS(INC(6,IH),INC(1,JH))=QSS(INQ(JH,IH,3))/HSIDE
PSS(INC(1,IH),INC(2,JH))=QSS(INQ(JH,IH,6))/HSIDE
PSS(INC(3,IH),INC(2,JH))=QSS(INQ(IH,JH,10))/HSIDE
PSS(INC(4,IH),INC(2,JH))=QSS(INQ(IH,JH,14))/HSIDE
PSS(INC(5,IH),INC(2,JH))=QSS(INQ(JH,IH,4))/HSIDE
PSS(INC(6,IH),INC(2,JH))=QSS(INQ(JH,IH,5))/HSIDE
PSS(INC(1,IH),INC(3,JH))=QSS(INQ(JH,IH,9))/HSIDE
PSS(INC(2,IH),INC(3,JH))=QSS(INQ(JH,IH,10))/HSIDE
PSS(INC(4,IH),INC(3,JH))=QSS(INQ(IH,JH,15))/HSIDE
PSS(INC(5,IH),INC(3,JH))=QSS(INQ(JH,IH,7))/HSIDE
PSS(INC(6,IH),INC(3,JH))=QSS(INQ(JH,IH,8))/HSIDE
PSS(INC(1,IH),INC(4,JH))=QSS(INQ(JH,IH,13))/HSIDE
PSS(INC(2,IH),INC(4,JH))=QSS(INQ(JH,IH,14))/HSIDE
PSS(INC(3,IH),INC(4,JH))=QSS(INQ(JH,IH,15))/HSIDE
PSS(INC(5,IH),INC(4,JH))=QSS(INQ(JH,IH,11))/HSIDE
PSS(INC(6,IH),INC(4,JH))=QSS(INQ(JH,IH,12))/HSIDE
PSS(INC(1,IH),INC(5,JH))=QSS(INQ(IH,JH,2))/HSIDE
PSS(INC(2,IH),INC(5,JH))=QSS(INQ(JH,IH,4))/HSIDE
PSS(INC(3,IH),INC(5,JH))=QSS(INQ(IH,JH,7))/HSIDE
PSS(INC(4,IH),INC(5,JH))=QSS(INQ(IH,JH,11))/HSIDE
PSS(INC(6,IH),INC(5,JH))=QSS(INQ(IH,JH,1))/HSIDE
PSS(INC(1,IH),INC(6,JH))=QSS(INQ(IH,JH,3))/HSIDE
PSS(INC(2,IH),INC(6,JH))=QSS(INQ(IH,JH,5))/HSIDE
PSS(INC(3,IH),INC(6,JH))=QSS(INQ(JH,IH,8))/HSIDE
PSS(INC(4,IH),INC(6,JH))=QSS(INQ(IH,JH,12))/HSIDE
PSS(INC(5,IH),INC(6,JH))=QSS(INQ(JH,IH,1))/HSIDE
300 CONTINUE
310 CONTINUE
*----
* SCRATCH STORAGE DEALLOCATION
*----
DEALLOCATE(LGFULL)
DEALLOCATE(G,PSIX,WORKIJ,VOLINT)
DEALLOCATE(NUMREG)
RETURN
END
|
