*DECK VALUE1 SUBROUTINE VALUE1 (IDIM,LX,LY,LZ,L4,X,Y,Z,XXX,YYY,ZZZ,EVT,ISS, 1 IELEM,IXLG,IYLG,IZLG,AXYZ) * *----------------------------------------------------------------------- * *Purpose: * Interpolate the flux distribution for MCFD method in 3D. * *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 * IDIM number of dimensions (1, 2 or 3). * LX number of elements along the X axis. * LY number of elements along the Y axis. * LZ number of elements along the Z axis. * L4 dimension of unknown array EVT. * X Cartesian coordinates along the X axis where the flux is * interpolated. * Y Cartesian coordinates along the Y axis where the flux is * interpolated. * Z Cartesian coordinates along the Z axis where the flux is * interpolated. * XXX Cartesian coordinates along the X axis. * YYY Cartesian coordinates along the Y axis. * ZZZ Cartesian coordinates along the Z axis. * EVT variational coefficients of the flux. * ISS mixture index assigned to each element. * IELEM MCFD polynomial order (IELEM=1 is the mesh centered finite * difference method). * IXLG number of interpolated points according to X. * IYLG number of interpolated points according to Y. * IZLG number of interpolated points according to Z. * *Parameters: output * AXYZ interpolated fluxes. * *---------------------------------------------------------------------- * *---- * SUBROUTINE ARGUMENTS *---- INTEGER IDIM,LX,LY,LZ,L4,ISS(LX*LY*LZ),IELEM,IXLG,IYLG,IZLG REAL X(IXLG),Y(IYLG),Z(IZLG),XXX(LX+1),YYY(LY+1),ZZZ(LZ+1), 1 EVT(L4),AXYZ(IXLG,IYLG,IZLG) *---- * ALLOCATABLE ARRAYS *---- INTEGER, ALLOCATABLE, DIMENSION(:) :: IWRK *---- * Scratch storage allocation *---- ALLOCATE(IWRK(LX*LY*LZ)) * NUM=0 DO 10 K=1,LX*LY*LZ IF (ISS(K).EQ.0) GO TO 10 NUM=NUM+1 IWRK(K)=NUM 10 CONTINUE * LL4=L4/IELEM**(IDIM-1) DO 130 K=1,IZLG COTE=Z(K) DO 120 J=1,IYLG ORDO=Y(J) DO 110 I=1,IXLG ABSC=X(I) GAR=0.0 * * Find the finite element index containing the interpolation point IS=0 JS=0 KS=0 DO 20 L=1,LX IS=L IF((ABSC.GE.XXX(L)).AND.(ABSC.LE.XXX(L+1))) GO TO 30 20 CONTINUE CALL XABORT('VALUE1: WRONG INTERPOLATION(1).') 30 DO 40 L=1,LY JS=L IF((ORDO.GE.YYY(L)).AND.(ORDO.LE.YYY(L+1))) GO TO 50 40 CONTINUE CALL XABORT('VALUE1: WRONG INTERPOLATION(2).') 50 DO 60 L=1,LZ KS=L IF((COTE.GE.ZZZ(L)).AND.(COTE.LE.ZZZ(L+1))) GO TO 70 60 CONTINUE CALL XABORT('VALUE1: WRONG INTERPOLATION(3).') 70 IEL=(KS-1)*LX*LY+(JS-1)*LX+IS IF(ISS(IEL).EQ.0) GO TO 100 U=(ABSC-0.5*(XXX(IS)+XXX(IS+1)))/(XXX(IS+1)-XXX(IS)) V=(ORDO-0.5*(YYY(JS)+YYY(JS+1)))/(YYY(JS+1)-YYY(JS)) W=(COTE-0.5*(ZZZ(KS)+ZZZ(KS+1)))/(ZZZ(KS+1)-ZZZ(KS)) L=1+IELEM*(IWRK(IEL)-1) DO 95 N3=0,IELEM-1 DO 90 N2=0,IELEM-1 DO 80 N1=0,IELEM-1 GAR=GAR+VALPL(N1,U)*VALPL(N2,V)*VALPL(N3,W)* 1 EVT(LL4*(IELEM*N3+N2)+N1+L) 80 CONTINUE IF ((IDIM.EQ.1).AND.(N2.EQ.0)) GO TO 100 IF ((IDIM.EQ.2).AND.(N2.EQ.IELEM-1)) GO TO 100 90 CONTINUE 95 CONTINUE 100 AXYZ(I,J,K)=GAR 110 CONTINUE 120 CONTINUE 130 CONTINUE *---- * Scratch storage deallocation *---- DEALLOCATE(IWRK) RETURN END