*DECK MCTALLY SUBROUTINE MCTALLY(ITALLY,NFREG,NMIX,NGRP,NL,NFM,NDEL,NED,NBSCO, 1 NMERGE,NGCOND,IREG,IGR,NU,MATCOD,IMERGE,INDGRP,XSM,XST,XSS, 2 XSN2N,XSN3N,XSSNN,XSNUSI,XSCHI,XSEDI,SCORE1,SCORE2) * *----------------------------------------------------------------------- * *Purpose: * Score for effective multiplication factor and macrolib information. * *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): A. Hebert * *Parameters: input * ITALLY type of tally (=1 score effective multiplication factor; * =2 also score macrolib information). * NFREG number of regions. * NMIX number of material mixtures. * NGRP number of energy groups. * NL number of Legendre orders required in the estimations * (NL=1 or higher). * NFM number of fissile isotopes. * NDEL number of delayed precursor groups. * NED number of extra edit vectors. * NBSCO number of macrolib-related scores. * NMERGE number of homogenized regions. * NGCOND number of condensed energy groups. * IREG index of the region where the particle is located. * IGR index of the energy group of the particle. * NU particle weight. * MATCOD region material. * IMERGE homogenized regions indices. * INDGRP condensed groups indices. * XSM maximum macroscopic total cross section. * XST total macroscopic cross sections for each mixture and energy * group. * XSS total scattering cross sections for each mixture and energy * group. * XSN2N N2N macroscopic cross sections for each mixture and energy * group. * XSN3N N3N macroscopic cross sections for each mixture and energy * group. * XSSNN in-group and out-of-group macroscopic transfert cross sections * for each mixture. * XSNUSI the values of Nu time the fission cross sections for each * isotope per mixture and energy group. * XSCHI fission spectrum for isotopes per mixture and energy group. * XSEDI extra edit cross sections for each mixture and energy group. * *Parameters: input/output * SCORE1 score for total flux and effective multiplication factor. * SCORE2 macrolib score matrix. * *----------------------------------------------------------------------- * IMPLICIT NONE *---- * SUBROUTINE ARGUMENTS *---- INTEGER ITALLY,NFREG,NMIX,NGRP,NL,NFM,NDEL,NED,NBSCO,NMERGE, 1 NGCOND,IREG,IGR,MATCOD(NFREG),IMERGE(NFREG),INDGRP(NGRP) REAL NU,XSM,XST(NMIX,NGRP),XSS(NMIX,NGRP,NL),XSN2N(NMIX,NGRP), 1 XSN3N(NMIX,NGRP),XSSNN(NMIX,NGRP,NGRP,NL), 2 XSNUSI(NMIX,NFM,NGRP,1+NDEL),XSCHI(NMIX,NFM,NGRP,1+NDEL), 3 XSEDI(NMIX,NGRP,NED),SCORE1(3),SCORE2(NBSCO,NMERGE,NGCOND) *---- * LOCAL VARIABLES *---- INTEGER IBM,IFM,IED,JGR,IBMCD,IGRCD,JGRCD,IOF,IL,IDEL REAL WW * WW=NU/XSM IF(IREG.GT.0) THEN SCORE1(1)=SCORE1(1)+WW IBM=MATCOD(IREG) IF(IBM.GT.0) THEN DO IFM=1,NFM SCORE1(2)=SCORE1(2)+WW*XSNUSI(IBM,IFM,IGR,1) ENDDO SCORE1(3)=SCORE1(3)+WW*(XST(IBM,IGR)-XSS(IBM,IGR,1)-2.0* 1 XSN2N(IBM,IGR)-3.0*XSN3N(IBM,IGR)) ENDIF IF(ITALLY.EQ.2) THEN IBMCD=IMERGE(IREG) IF(IBMCD.EQ.0) GO TO 10 IGRCD=INDGRP(IGR) IF(IGRCD.EQ.0) GO TO 10 SCORE2(1,IBMCD,IGRCD)=SCORE2(1,IBMCD,IGRCD)+WW IF(IBM.EQ.0) GO TO 10 SCORE2(2,IBMCD,IGRCD)=SCORE2(2,IBMCD,IGRCD)+WW*XST(IBM,IGR) SCORE2(3,IBMCD,IGRCD)=SCORE2(3,IBMCD,IGRCD)+WW*XSS(IBM,IGR,1) SCORE2(4,IBMCD,IGRCD)=SCORE2(4,IBMCD,IGRCD)+WW*XSN2N(IBM,IGR) SCORE2(5,IBMCD,IGRCD)=SCORE2(5,IBMCD,IGRCD)+WW*XSN3N(IBM,IGR) IOF=5 DO IL=1,NL DO JGR=1,NGRP JGRCD=INDGRP(JGR) SCORE2(IOF+JGRCD,IBMCD,IGRCD)=SCORE2(IOF+JGRCD,IBMCD,IGRCD) 1 +WW*XSSNN(IBM,JGR,IGR,IL) ENDDO IOF=IOF+NGCOND ENDDO DO IDEL=1,1+NDEL DO IFM=1,NFM SCORE2(IOF+IFM,IBMCD,IGRCD)=SCORE2(IOF+IFM,IBMCD,IGRCD)+ 1 WW*XSNUSI(IBM,IFM,IGR,IDEL) ENDDO IOF=IOF+NFM DO IFM=1,NFM DO JGR=1,NGRP JGRCD=INDGRP(JGR) SCORE2(IOF+IFM,IBMCD,JGRCD)=SCORE2(IOF+IFM,IBMCD,JGRCD)+ 1 WW*XSNUSI(IBM,IFM,IGR,IDEL)*XSCHI(IBM,IFM,JGR,IDEL) ENDDO ENDDO IOF=IOF+NFM ENDDO DO IED=1,NED SCORE2(IOF+IED,IBMCD,IGRCD)=SCORE2(IOF+IED,IBMCD,IGRCD)+WW* 1 XSEDI(IBM,IGR,IED) ENDDO ENDIF ENDIF 10 RETURN END