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jmc |
1.40 |
C $Header: /u/gcmpack/MITgcm/model/src/ini_cg2d.F,v 1.39 2002/06/21 18:36:05 adcroft Exp $ |
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jmc |
1.30 |
C $Name: $ |
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cnh |
1.1 |
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adcroft |
1.13 |
#include "CPP_OPTIONS.h" |
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cnh |
1.1 |
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cnh |
1.37 |
CBOP |
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C !ROUTINE: INI_CG2D |
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C !INTERFACE: |
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cnh |
1.1 |
SUBROUTINE INI_CG2D( myThid ) |
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cnh |
1.37 |
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C !DESCRIPTION: \bv |
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C *==========================================================* |
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C | SUBROUTINE INI_CG2D |
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C | o Initialise 2d conjugate gradient solver operators. |
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C *==========================================================* |
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C | These arrays are purely a function of the basin geom. |
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C | We set then here once and them use then repeatedly. |
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C *==========================================================* |
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C \ev |
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C !USES: |
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adcroft |
1.23 |
IMPLICIT NONE |
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cnh |
1.1 |
C === Global variables === |
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#include "SIZE.h" |
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#include "EEPARAMS.h" |
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#include "PARAMS.h" |
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#include "GRID.h" |
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adcroft |
1.34 |
c#include "DYNVARS.h" |
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jmc |
1.31 |
#include "SURFACE.h" |
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adcroft |
1.34 |
#include "CG2D.h" |
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adcroft |
1.26 |
#ifdef ALLOW_OBCS |
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adcroft |
1.22 |
#include "OBCS.h" |
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adcroft |
1.26 |
#endif |
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cnh |
1.1 |
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cnh |
1.37 |
C !INPUT/OUTPUT PARAMETERS: |
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cnh |
1.1 |
C === Routine arguments === |
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C myThid - Thread no. that called this routine. |
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INTEGER myThid |
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cnh |
1.37 |
C !LOCAL VARIABLES: |
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cnh |
1.1 |
C === Local variables === |
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C xG, yG - Global coordinate location. |
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C zG |
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C iG, jG - Global coordinate index |
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C bi,bj - Loop counters |
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C faceArea - Temporary used to hold cell face areas. |
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C I,J,K |
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adcroft |
1.34 |
C myNorm - Work variable used in calculating normalisation factor |
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C sumArea - Work variable used to compute the total Domain Area |
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cnh |
1.1 |
CHARACTER*(MAX_LEN_MBUF) msgBuf |
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INTEGER bi, bj |
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INTEGER I, J, K |
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cnh |
1.7 |
_RL faceArea |
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cnh |
1.15 |
_RS myNorm |
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adcroft |
1.34 |
_RL sumArea |
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cnh |
1.4 |
_RL aC, aCw, aCs |
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cnh |
1.37 |
CEOP |
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jmc |
1.38 |
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C-- Initialize arrays in common blocs (CG2D.h) ; not really necessary |
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C but safer when EXCH do not fill all the overlap regions. |
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DO bj=myByLo(myThid),myByHi(myThid) |
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DO bi=myBxLo(myThid),myBxHi(myThid) |
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DO J=1-OLy,sNy+OLy |
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DO I=1-OLx,sNx+OLx |
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aW2d(I,J,bi,bj) = 0. _d 0 |
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aS2d(I,J,bi,bj) = 0. _d 0 |
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pW(I,J,bi,bj) = 0. _d 0 |
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pS(I,J,bi,bj) = 0. _d 0 |
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pC(I,J,bi,bj) = 0. _d 0 |
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cg2d_q(I,J,bi,bj) = 0. _d 0 |
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ENDDO |
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ENDDO |
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DO J=1-1,sNy+1 |
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DO I=1-1,sNx+1 |
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cg2d_r(I,J,bi,bj) = 0. _d 0 |
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cg2d_s(I,J,bi,bj) = 0. _d 0 |
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ENDDO |
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ENDDO |
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ENDDO |
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ENDDO |
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jmc |
1.31 |
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cnh |
1.1 |
C-- Initialise laplace operator |
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C aW2d: integral in Z Ax/dX |
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C aS2d: integral in Z Ay/dY |
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myNorm = 0. _d 0 |
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DO bj=myByLo(myThid),myByHi(myThid) |
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DO bi=myBxLo(myThid),myBxHi(myThid) |
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DO J=1,sNy |
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DO I=1,sNx |
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aW2d(I,J,bi,bj) = 0. _d 0 |
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aS2d(I,J,bi,bj) = 0. _d 0 |
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ENDDO |
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ENDDO |
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cnh |
1.17 |
DO K=1,Nr |
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cnh |
1.1 |
DO J=1,sNy |
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DO I=1,sNx |
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cnh |
1.20 |
faceArea = _dyG(I,J,bi,bj)*drF(K) |
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& *_hFacW(I,J,K,bi,bj) |
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cnh |
1.1 |
aW2d(I,J,bi,bj) = aW2d(I,J,bi,bj) + |
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jmc |
1.32 |
& implicSurfPress*implicDiv2DFlow |
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& *faceArea*recip_dxC(I,J,bi,bj) |
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cnh |
1.20 |
faceArea = _dxG(I,J,bi,bj)*drF(K) |
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& *_hFacS(I,J,K,bi,bj) |
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cnh |
1.1 |
aS2d(I,J,bi,bj) = aS2d(I,J,bi,bj) + |
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jmc |
1.32 |
& implicSurfPress*implicDiv2DFlow |
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& *faceArea*recip_dyC(I,J,bi,bj) |
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cnh |
1.1 |
ENDDO |
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ENDDO |
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ENDDO |
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adcroft |
1.26 |
#ifdef ALLOW_OBCS |
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adcroft |
1.28 |
IF (useOBCS) THEN |
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adcroft |
1.22 |
DO I=1,sNx |
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IF (OB_Jn(I,bi,bj).NE.0) aS2d(I,OB_Jn(I,bi,bj),bi,bj)=0. |
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IF (OB_Jn(I,bi,bj).NE.0) aS2d(I,OB_Jn(I,bi,bj)+1,bi,bj)=0. |
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IF (OB_Js(I,bi,bj).NE.0) aS2d(I,OB_Js(I,bi,bj)+1,bi,bj)=0. |
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IF (OB_Js(I,bi,bj).NE.0) aS2d(I,OB_Js(I,bi,bj),bi,bj)=0. |
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ENDDO |
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DO J=1,sNy |
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IF (OB_Ie(J,bi,bj).NE.0) aW2d(OB_Ie(J,bi,bj),J,bi,bj)=0. |
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IF (OB_Ie(J,bi,bj).NE.0) aW2d(OB_Ie(J,bi,bj)+1,J,bi,bj)=0. |
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IF (OB_Iw(J,bi,bj).NE.0) aW2d(OB_Iw(J,bi,bj)+1,J,bi,bj)=0. |
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IF (OB_Iw(J,bi,bj).NE.0) aW2d(OB_Iw(J,bi,bj),J,bi,bj)=0. |
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ENDDO |
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ENDIF |
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adcroft |
1.26 |
#endif |
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cnh |
1.1 |
DO J=1,sNy |
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DO I=1,sNx |
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myNorm = MAX(ABS(aW2d(I,J,bi,bj)),myNorm) |
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myNorm = MAX(ABS(aS2d(I,J,bi,bj)),myNorm) |
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ENDDO |
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ENDDO |
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ENDDO |
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ENDDO |
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adcroft |
1.25 |
_GLOBAL_MAX_R4( myNorm, myThid ) |
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IF ( myNorm .NE. 0. _d 0 ) THEN |
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myNorm = 1. _d 0/myNorm |
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cnh |
1.1 |
ELSE |
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myNorm = 1. _d 0 |
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ENDIF |
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cnh |
1.5 |
cg2dNorm = myNorm |
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cnh |
1.1 |
_BEGIN_MASTER( myThid ) |
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CcnhDebugStarts |
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cnh |
1.20 |
WRITE(msgBuf,'(A,E40.25)') '// CG2D normalisation factor = ', |
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& cg2dNorm |
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cnh |
1.3 |
CALL PRINT_MESSAGE( msgBuf,standardMessageUnit,SQUEEZE_RIGHT,1) |
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WRITE(msgBuf,*) ' ' |
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cnh |
1.1 |
CALL PRINT_MESSAGE( msgBuf,standardMessageUnit,SQUEEZE_RIGHT,1) |
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CcnhDebugEnds |
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_END_MASTER( myThid ) |
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DO bj=myByLo(myThid),myByHi(myThid) |
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DO bi=myBxLo(myThid),myBxHi(myThid) |
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DO J=1,sNy |
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DO I=1,sNx |
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aW2d(I,J,bi,bj) = aW2d(I,J,bi,bj)*myNorm |
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aS2d(I,J,bi,bj) = aS2d(I,J,bi,bj)*myNorm |
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ENDDO |
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ENDDO |
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ENDDO |
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ENDDO |
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C-- Update overlap regions |
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CcnhDebugStarts |
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cnh |
1.14 |
C CALL PLOT_FIELD_XYRS( aW2d, 'AW2D INI_CG2D.1' , 1, myThid ) |
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C CALL PLOT_FIELD_XYRS( aS2d, 'AS2D INI_CG2D.1' , 1, myThid ) |
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cnh |
1.1 |
CcnhDebugEnds |
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adcroft |
1.34 |
c _EXCH_XY_R4(aW2d, myThid) |
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c _EXCH_XY_R4(aS2d, myThid) |
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CALL EXCH_UV_XY_RS(aW2d,aS2d,.FALSE.,myThid) |
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cnh |
1.1 |
CcnhDebugStarts |
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adcroft |
1.24 |
C CALL PLOT_FIELD_XYRS( aW2d, 'AW2D INI_CG2D.2' , 1, myThid ) |
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C CALL PLOT_FIELD_XYRS( aS2d, 'AS2D INI_CG2D.2' , 1, myThid ) |
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cnh |
1.1 |
CcnhDebugEnds |
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adcroft |
1.34 |
C-- Define the solver tolerance in the appropriate Unit : |
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cg2dNormaliseRHS = cg2dTargetResWunit.LE.0 |
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IF (cg2dNormaliseRHS) THEN |
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C- when using a normalisation of RHS, tolerance has no unit => no conversion |
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cg2dTolerance = cg2dTargetResidual |
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ELSE |
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C- compute the total Area of the domain : |
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sumArea = 0. |
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DO bj=myByLo(myThid),myByHi(myThid) |
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DO bi=myBxLo(myThid),myBxHi(myThid) |
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DO j=1,sNy |
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DO i=1,sNx |
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IF (Ro_surf(i,j,bi,bj).GT.R_low(i,j,bi,bj)) THEN |
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sumArea = sumArea + rA(i,j,bi,bj) |
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ENDIF |
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ENDDO |
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ENDDO |
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ENDDO |
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ENDDO |
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adcroft |
1.35 |
c WRITE(*,*) ' mythid, sumArea = ', mythid, sumArea |
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adcroft |
1.34 |
_GLOBAL_SUM_R8( sumArea, myThid ) |
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C- convert Target-Residual (in W unit) to cg2d-solver residual unit [m^2/s^2] |
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cg2dTolerance = cg2dNorm * cg2dTargetResWunit |
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adcroft |
1.39 |
& * sumArea / deltaTfreesurf |
198 |
jmc |
1.40 |
_BEGIN_MASTER( myThid ) |
199 |
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WRITE(standardMessageUnit,'(2A,1P2E22.14)') ' ini_cg2d: ', |
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adcroft |
1.34 |
& 'sumArea,cg2dTolerance =', sumArea,cg2dTolerance |
201 |
jmc |
1.40 |
_END_MASTER( myThid ) |
202 |
adcroft |
1.34 |
ENDIF |
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204 |
cnh |
1.1 |
C-- Initialise preconditioner |
205 |
cnh |
1.4 |
C Note. 20th May 1998 |
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C I made a weird discovery! In the model paper we argue |
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C for the form of the preconditioner used here ( see |
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C A Finite-volume, Incompressible Navier-Stokes Model |
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C ...., Marshall et. al ). The algebra gives a simple |
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C 0.5 factor for the averaging of ac and aCw to get a |
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C symmettric pre-conditioner. By using a factor of 0.51 |
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C i.e. scaling the off-diagonal terms in the |
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C preconditioner down slightly I managed to get the |
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C number of iterations for convergence in a test case to |
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C drop form 192 -> 134! Need to investigate this further! |
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C For now I have introduced a parameter cg2dpcOffDFac which |
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C defaults to 0.51 but can be set at runtime. |
218 |
cnh |
1.1 |
DO bj=myByLo(myThid),myByHi(myThid) |
219 |
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DO bi=myBxLo(myThid),myBxHi(myThid) |
220 |
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DO J=1,sNy |
221 |
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DO I=1,sNx |
222 |
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pC(I,J,bi,bj) = 1. _d 0 |
223 |
cnh |
1.4 |
aC = -( |
224 |
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& aW2d(I,J,bi,bj) + aW2d(I+1,J ,bi,bj) |
225 |
adcroft |
1.24 |
& +aS2d(I,J,bi,bj) + aS2d(I ,J+1,bi,bj) |
226 |
jmc |
1.32 |
& +freeSurfFac*myNorm*recip_Bo(I,J,bi,bj)* |
227 |
adcroft |
1.39 |
& rA(I,J,bi,bj)/deltaTMom/deltaTfreesurf |
228 |
cnh |
1.4 |
& ) |
229 |
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aCs = -( |
230 |
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& aW2d(I,J-1,bi,bj) + aW2d(I+1,J-1,bi,bj) |
231 |
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& +aS2d(I,J-1,bi,bj) + aS2d(I ,J ,bi,bj) |
232 |
jmc |
1.32 |
& +freeSurfFac*myNorm*recip_Bo(I,J-1,bi,bj)* |
233 |
adcroft |
1.39 |
& rA(I,J-1,bi,bj)/deltaTMom/deltaTfreesurf |
234 |
cnh |
1.4 |
& ) |
235 |
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aCw = -( |
236 |
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& aW2d(I-1,J,bi,bj) + aW2d(I ,J ,bi,bj) |
237 |
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& +aS2d(I-1,J,bi,bj) + aS2d(I-1,J+1,bi,bj) |
238 |
jmc |
1.32 |
& +freeSurfFac*myNorm*recip_Bo(I-1,J,bi,bj)* |
239 |
adcroft |
1.39 |
& rA(I-1,J,bi,bj)/deltaTMom/deltaTfreesurf |
240 |
cnh |
1.4 |
& ) |
241 |
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IF ( aC .EQ. 0. ) THEN |
242 |
adcroft |
1.27 |
pC(I,J,bi,bj) = 1. _d 0 |
243 |
cnh |
1.4 |
ELSE |
244 |
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pC(I,J,bi,bj) = 1. _d 0 / aC |
245 |
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ENDIF |
246 |
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IF ( aC + aCw .EQ. 0. ) THEN |
247 |
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pW(I,J,bi,bj) = 0. |
248 |
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ELSE |
249 |
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pW(I,J,bi,bj) = |
250 |
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& -aW2d(I ,J ,bi,bj)/((cg2dpcOffDFac *(aCw+aC))**2 ) |
251 |
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ENDIF |
252 |
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IF ( aC + aCs .EQ. 0. ) THEN |
253 |
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pS(I,J,bi,bj) = 0. |
254 |
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ELSE |
255 |
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pS(I,J,bi,bj) = |
256 |
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& -aS2d(I ,J ,bi,bj)/((cg2dpcOffDFac *(aCs+aC))**2 ) |
257 |
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ENDIF |
258 |
cnh |
1.6 |
C pC(I,J,bi,bj) = 1. |
259 |
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C pW(I,J,bi,bj) = 0. |
260 |
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C pS(I,J,bi,bj) = 0. |
261 |
cnh |
1.1 |
ENDDO |
262 |
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ENDDO |
263 |
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ENDDO |
264 |
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ENDDO |
265 |
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C-- Update overlap regions |
266 |
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_EXCH_XY_R4(pC, myThid) |
267 |
adcroft |
1.34 |
c _EXCH_XY_R4(pW, myThid) |
268 |
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c _EXCH_XY_R4(pS, myThid) |
269 |
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CALL EXCH_UV_XY_RS(pW,pS,.FALSE.,myThid) |
270 |
cnh |
1.18 |
CcnhDebugStarts |
271 |
adcroft |
1.24 |
C CALL PLOT_FIELD_XYRS( pC, 'pC INI_CG2D.2' , 1, myThid ) |
272 |
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C CALL PLOT_FIELD_XYRS( pW, 'pW INI_CG2D.2' , 1, myThid ) |
273 |
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C CALL PLOT_FIELD_XYRS( pS, 'pS INI_CG2D.2' , 1, myThid ) |
274 |
cnh |
1.18 |
CcnhDebugEnds |
275 |
cnh |
1.1 |
|
276 |
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RETURN |
277 |
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END |