! ! $Header$ ! SUBROUTINE ADVYP(LIMIT,DTY,PBARV,SM,S0,SSX,SY,SZ . ,SSXX,SSXY,SSXZ,SYY,SYZ,SZZ,ntra ) IMPLICIT NONE CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC C C C second-order moments (SOM) advection of tracer in Y direction C C C CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC C C C Source : Pascal Simon ( Meteo, CNRM ) C C Adaptation : A.A. (LGGE) C C Derniere Modif : 19/10/95 LAST C C C sont les arguments d'entree pour le s-pg C C C C argument de sortie du s-pg C C C CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC C C Rem : Probleme aux poles il faut reecrire ce cas specifique C Attention au sens de l'indexation C C parametres principaux du modele C C #include "dimensions.h" #include "paramet.h" #include "comgeom.h" C Arguments : C ---------- C dty : frequence fictive d'appel du transport C parbu,pbarv : flux de masse en x et y en Pa.m2.s-1 INTEGER lon,lat,niv INTEGER i,j,jv,k,kp,l INTEGER ntra C PARAMETER (ntra = 1) REAL dty REAL pbarv ( iip1,jjm, llm ) C moments: SM total mass in each grid box C S0 mass of tracer in each grid box C Si 1rst order moment in i direction C REAL SM(iip1,jjp1,llm) + ,S0(iip1,jjp1,llm,ntra) REAL SSX(iip1,jjp1,llm,ntra) + ,SY(iip1,jjp1,llm,ntra) + ,SZ(iip1,jjp1,llm,ntra) + ,SSXX(iip1,jjp1,llm,ntra) + ,SSXY(iip1,jjp1,llm,ntra) + ,SSXZ(iip1,jjp1,llm,ntra) + ,SYY(iip1,jjp1,llm,ntra) + ,SYZ(iip1,jjp1,llm,ntra) + ,SZZ(iip1,jjp1,llm,ntra) C C Local : C ------- C mass fluxes across the boundaries (UGRI,VGRI,WGRI) C mass fluxes in kg C declaration : REAL VGRI(iip1,0:jjp1,llm) C Rem : UGRI et WGRI ne sont pas utilises dans C cette subroutine ( advection en y uniquement ) C Rem 2 :le dimensionnement de VGRI depend de celui de pbarv C C the moments F are similarly defined and used as temporary C storage for portions of the grid boxes in transit C C the moments Fij are used as temporary storage for C portions of the grid boxes in transit at the current level C C work arrays C C REAL F0(iim,0:jjp1,ntra),FM(iim,0:jjp1) REAL FX(iim,jjm,ntra),FY(iim,jjm,ntra) REAL FZ(iim,jjm,ntra) REAL FXX(iim,jjm,ntra),FXY(iim,jjm,ntra) REAL FXZ(iim,jjm,ntra),FYY(iim,jjm,ntra) REAL FYZ(iim,jjm,ntra),FZZ(iim,jjm,ntra) REAL S00(ntra) REAL SM0 ! Just temporal variable C C work arrays C REAL ALF(iim,0:jjp1),ALF1(iim,0:jjp1) REAL ALFQ(iim,0:jjp1),ALF1Q(iim,0:jjp1) REAL ALF2(iim,0:jjp1),ALF3(iim,0:jjp1) REAL ALF4(iim,0:jjp1) REAL TEMPTM ! Just temporal variable REAL SLPMAX,S1MAX,S1NEW,S2NEW c C Special pour poles c REAL sbms,sfms,sfzs,sbmn,sfmn,sfzn REAL sns0(ntra),snsz(ntra),snsm REAL qy1(iim,llm,ntra),qylat(iim,llm,ntra) REAL cx1(llm,ntra), cxLAT(llm,ntra) REAL cy1(llm,ntra), cyLAT(llm,ntra) REAL z1(iim), zcos(iim), zsin(iim) REAL SSUM EXTERNAL SSUM C REAL sqi,sqf LOGICAL LIMIT lon = iim ! rem : Il est possible qu'un pbl. arrive ici lat = jjp1 ! a cause des dim. differentes entre les niv = llm ! tab. S et VGRI c----------------------------------------------------------------- C initialisations sbms = 0. sfms = 0. sfzs = 0. sbmn = 0. sfmn = 0. sfzn = 0. c----------------------------------------------------------------- C *** Test : diag de la qtite totale de traceur dans C l'atmosphere avant l'advection en Y c sqi = 0. sqf = 0. DO l = 1,llm DO j = 1,jjp1 DO i = 1,iim sqi = sqi + S0(i,j,l,ntra) END DO END DO END DO PRINT*,'---------- DIAG DANS ADVY - ENTREE --------' PRINT*,'sqi=',sqi c----------------------------------------------------------------- C Interface : adaptation nouveau modele C ------------------------------------- C C Conversion des flux de masses en kg C-AA 20/10/94 le signe -1 est necessaire car indexation opposee DO 500 l = 1,llm DO 500 j = 1,jjm DO 500 i = 1,iip1 vgri (i,j,llm+1-l)=-1.*pbarv (i,j,l) 500 CONTINUE CAA Initialisation de flux fictifs aux bords sup. des boites pol. DO l = 1,llm DO i = 1,iip1 vgri(i,0,l) = 0. vgri(i,jjp1,l) = 0. ENDDO ENDDO c c----------------- START HERE ----------------------- C boucle sur les niveaux C DO 1 L=1,NIV C C place limits on appropriate moments before transport C (if flux-limiting is to be applied) C IF(.NOT.LIMIT) GO TO 11 C DO 10 JV=1,NTRA DO 10 K=1,LAT DO 100 I=1,LON IF(S0(I,K,L,JV).GT.0.) THEN SLPMAX=AMAX1(S0(I,K,L,JV),0.) S1MAX=1.5*SLPMAX S1NEW=AMIN1(S1MAX,AMAX1(-S1MAX,SY(I,K,L,JV))) S2NEW=AMIN1( 2.*SLPMAX-ABS(S1NEW)/3. , + AMAX1(ABS(S1NEW)-SLPMAX,SYY(I,K,L,JV)) ) SY (I,K,L,JV)=S1NEW SYY(I,K,L,JV)=S2NEW SSXY(I,K,L,JV)=AMIN1(SLPMAX,AMAX1(-SLPMAX,SSXY(I,K,L,JV))) SYZ(I,K,L,JV)=AMIN1(SLPMAX,AMAX1(-SLPMAX,SYZ(I,K,L,JV))) ELSE SY (I,K,L,JV)=0. SYY(I,K,L,JV)=0. SSXY(I,K,L,JV)=0. SYZ(I,K,L,JV)=0. ENDIF 100 CONTINUE 10 CONTINUE C 11 CONTINUE C C le flux a travers le pole Nord est traite separement C SM0=0. DO 20 JV=1,NTRA S00(JV)=0. 20 CONTINUE C DO 21 I=1,LON C IF(VGRI(I,0,L).LE.0.) THEN FM(I,0)=-VGRI(I,0,L)*DTY ALF(I,0)=FM(I,0)/SM(I,1,L) SM(I,1,L)=SM(I,1,L)-FM(I,0) SM0=SM0+FM(I,0) ENDIF C ALFQ(I,0)=ALF(I,0)*ALF(I,0) ALF1(I,0)=1.-ALF(I,0) ALF1Q(I,0)=ALF1(I,0)*ALF1(I,0) ALF2(I,0)=ALF1(I,0)-ALF(I,0) ALF3(I,0)=ALF(I,0)*ALFQ(I,0) ALF4(I,0)=ALF1(I,0)*ALF1Q(I,0) C 21 CONTINUE c print*,'ADVYP 21' C DO 22 JV=1,NTRA DO 220 I=1,LON C IF(VGRI(I,0,L).LE.0.) THEN C F0(I,0,JV)=ALF(I,0)* ( S0(I,1,L,JV)-ALF1(I,0)* + ( SY(I,1,L,JV)-ALF2(I,0)*SYY(I,1,L,JV) ) ) C S00(JV)=S00(JV)+F0(I,0,JV) S0 (I,1,L,JV)=S0(I,1,L,JV)-F0(I,0,JV) SY (I,1,L,JV)=ALF1Q(I,0)* + (SY(I,1,L,JV)+3.*ALF(I,0)*SYY(I,1,L,JV)) SYY(I,1,L,JV)=ALF4 (I,0)*SYY(I,1,L,JV) SSX (I,1,L,JV)=ALF1 (I,0)* + (SSX(I,1,L,JV)+ALF(I,0)*SSXY(I,1,L,JV) ) SZ (I,1,L,JV)=ALF1 (I,0)* + (SZ(I,1,L,JV)+ALF(I,0)*SSXZ(I,1,L,JV) ) SSXX(I,1,L,JV)=ALF1 (I,0)*SSXX(I,1,L,JV) SSXZ(I,1,L,JV)=ALF1 (I,0)*SSXZ(I,1,L,JV) SZZ(I,1,L,JV)=ALF1 (I,0)*SZZ(I,1,L,JV) SSXY(I,1,L,JV)=ALF1Q(I,0)*SSXY(I,1,L,JV) SYZ(I,1,L,JV)=ALF1Q(I,0)*SYZ(I,1,L,JV) C ENDIF C 220 CONTINUE 22 CONTINUE C DO 23 I=1,LON IF(VGRI(I,0,L).GT.0.) THEN FM(I,0)=VGRI(I,0,L)*DTY ALF(I,0)=FM(I,0)/SM0 ENDIF 23 CONTINUE C DO 24 JV=1,NTRA DO 240 I=1,LON IF(VGRI(I,0,L).GT.0.) THEN F0(I,0,JV)=ALF(I,0)*S00(JV) ENDIF 240 CONTINUE 24 CONTINUE C C puts the temporary moments Fi into appropriate neighboring boxes C c print*,'av ADVYP 25' DO 25 I=1,LON C IF(VGRI(I,0,L).GT.0.) THEN SM(I,1,L)=SM(I,1,L)+FM(I,0) ALF(I,0)=FM(I,0)/SM(I,1,L) ENDIF C ALFQ(I,0)=ALF(I,0)*ALF(I,0) ALF1(I,0)=1.-ALF(I,0) ALF1Q(I,0)=ALF1(I,0)*ALF1(I,0) ALF2(I,0)=ALF1(I,0)-ALF(I,0) ALF3(I,0)=ALF1(I,0)*ALF(I,0) C 25 CONTINUE c print*,'av ADVYP 25' C DO 26 JV=1,NTRA DO 260 I=1,LON C IF(VGRI(I,0,L).GT.0.) THEN C TEMPTM=ALF(I,0)*S0(I,1,L,JV)-ALF1(I,0)*F0(I,0,JV) S0 (I,1,L,JV)=S0(I,1,L,JV)+F0(I,0,JV) SYY(I,1,L,JV)=ALF1Q(I,0)*SYY(I,1,L,JV) + +5.*( ALF3 (I,0)*SY (I,1,L,JV)-ALF2(I,0)*TEMPTM ) SY (I,1,L,JV)=ALF1 (I,0)*SY (I,1,L,JV)+3.*TEMPTM SSXY(I,1,L,JV)=ALF1 (I,0)*SSXY(I,1,L,JV)+3.*ALF(I,0)*SSX(I,1,L,JV) SYZ(I,1,L,JV)=ALF1 (I,0)*SYZ(I,1,L,JV)+3.*ALF(I,0)*SZ(I,1,L,JV) C ENDIF C 260 CONTINUE 26 CONTINUE C C calculate flux and moments between adjacent boxes C 1- create temporary moments/masses for partial boxes in transit C 2- reajusts moments remaining in the box C C flux from KP to K if V(K).lt.0 and from K to KP if V(K).gt.0 C c print*,'av ADVYP 30' DO 30 K=1,LAT-1 KP=K+1 DO 300 I=1,LON C IF(VGRI(I,K,L).LT.0.) THEN FM(I,K)=-VGRI(I,K,L)*DTY ALF(I,K)=FM(I,K)/SM(I,KP,L) SM(I,KP,L)=SM(I,KP,L)-FM(I,K) ELSE FM(I,K)=VGRI(I,K,L)*DTY ALF(I,K)=FM(I,K)/SM(I,K,L) SM(I,K,L)=SM(I,K,L)-FM(I,K) ENDIF C ALFQ(I,K)=ALF(I,K)*ALF(I,K) ALF1(I,K)=1.-ALF(I,K) ALF1Q(I,K)=ALF1(I,K)*ALF1(I,K) ALF2(I,K)=ALF1(I,K)-ALF(I,K) ALF3(I,K)=ALF(I,K)*ALFQ(I,K) ALF4(I,K)=ALF1(I,K)*ALF1Q(I,K) C 300 CONTINUE 30 CONTINUE c print*,'ap ADVYP 30' C DO 31 JV=1,NTRA DO 31 K=1,LAT-1 KP=K+1 DO 310 I=1,LON C IF(VGRI(I,K,L).LT.0.) THEN C F0 (I,K,JV)=ALF (I,K)* ( S0(I,KP,L,JV)-ALF1(I,K)* + ( SY(I,KP,L,JV)-ALF2(I,K)*SYY(I,KP,L,JV) ) ) FY (I,K,JV)=ALFQ(I,K)* + (SY(I,KP,L,JV)-3.*ALF1(I,K)*SYY(I,KP,L,JV)) FYY(I,K,JV)=ALF3(I,K)*SYY(I,KP,L,JV) FX (I,K,JV)=ALF (I,K)* + (SSX(I,KP,L,JV)-ALF1(I,K)*SSXY(I,KP,L,JV)) FZ (I,K,JV)=ALF (I,K)* + (SZ(I,KP,L,JV)-ALF1(I,K)*SYZ(I,KP,L,JV)) FXY(I,K,JV)=ALFQ(I,K)*SSXY(I,KP,L,JV) FYZ(I,K,JV)=ALFQ(I,K)*SYZ(I,KP,L,JV) FXX(I,K,JV)=ALF (I,K)*SSXX(I,KP,L,JV) FXZ(I,K,JV)=ALF (I,K)*SSXZ(I,KP,L,JV) FZZ(I,K,JV)=ALF (I,K)*SZZ(I,KP,L,JV) C S0 (I,KP,L,JV)=S0(I,KP,L,JV)-F0(I,K,JV) SY (I,KP,L,JV)=ALF1Q(I,K)* + (SY(I,KP,L,JV)+3.*ALF(I,K)*SYY(I,KP,L,JV)) SYY(I,KP,L,JV)=ALF4(I,K)*SYY(I,KP,L,JV) SSX (I,KP,L,JV)=SSX (I,KP,L,JV)-FX (I,K,JV) SZ (I,KP,L,JV)=SZ (I,KP,L,JV)-FZ (I,K,JV) SSXX(I,KP,L,JV)=SSXX(I,KP,L,JV)-FXX(I,K,JV) SSXZ(I,KP,L,JV)=SSXZ(I,KP,L,JV)-FXZ(I,K,JV) SZZ(I,KP,L,JV)=SZZ(I,KP,L,JV)-FZZ(I,K,JV) SSXY(I,KP,L,JV)=ALF1Q(I,K)*SSXY(I,KP,L,JV) SYZ(I,KP,L,JV)=ALF1Q(I,K)*SYZ(I,KP,L,JV) C ELSE C F0 (I,K,JV)=ALF (I,K)* ( S0(I,K,L,JV)+ALF1(I,K)* + ( SY(I,K,L,JV)+ALF2(I,K)*SYY(I,K,L,JV) ) ) FY (I,K,JV)=ALFQ(I,K)* + (SY(I,K,L,JV)+3.*ALF1(I,K)*SYY(I,K,L,JV)) FYY(I,K,JV)=ALF3(I,K)*SYY(I,K,L,JV) FX (I,K,JV)=ALF (I,K)*(SSX(I,K,L,JV)+ALF1(I,K)*SSXY(I,K,L,JV)) FZ (I,K,JV)=ALF (I,K)*(SZ(I,K,L,JV)+ALF1(I,K)*SYZ(I,K,L,JV)) FXY(I,K,JV)=ALFQ(I,K)*SSXY(I,K,L,JV) FYZ(I,K,JV)=ALFQ(I,K)*SYZ(I,K,L,JV) FXX(I,K,JV)=ALF (I,K)*SSXX(I,K,L,JV) FXZ(I,K,JV)=ALF (I,K)*SSXZ(I,K,L,JV) FZZ(I,K,JV)=ALF (I,K)*SZZ(I,K,L,JV) C S0 (I,K,L,JV)=S0 (I,K,L,JV)-F0 (I,K,JV) SY (I,K,L,JV)=ALF1Q(I,K)* + (SY(I,K,L,JV)-3.*ALF(I,K)*SYY(I,K,L,JV)) SYY(I,K,L,JV)=ALF4(I,K)*SYY(I,K,L,JV) SSX (I,K,L,JV)=SSX (I,K,L,JV)-FX (I,K,JV) SZ (I,K,L,JV)=SZ (I,K,L,JV)-FZ (I,K,JV) SSXX(I,K,L,JV)=SSXX(I,K,L,JV)-FXX(I,K,JV) SSXZ(I,K,L,JV)=SSXZ(I,K,L,JV)-FXZ(I,K,JV) SZZ(I,K,L,JV)=SZZ(I,K,L,JV)-FZZ(I,K,JV) SSXY(I,K,L,JV)=ALF1Q(I,K)*SSXY(I,K,L,JV) SYZ(I,K,L,JV)=ALF1Q(I,K)*SYZ(I,K,L,JV) C ENDIF C 310 CONTINUE 31 CONTINUE c print*,'ap ADVYP 31' C C puts the temporary moments Fi into appropriate neighboring boxes C DO 32 K=1,LAT-1 KP=K+1 DO 320 I=1,LON C IF(VGRI(I,K,L).LT.0.) THEN SM(I,K,L)=SM(I,K,L)+FM(I,K) ALF(I,K)=FM(I,K)/SM(I,K,L) ELSE SM(I,KP,L)=SM(I,KP,L)+FM(I,K) ALF(I,K)=FM(I,K)/SM(I,KP,L) ENDIF C ALFQ(I,K)=ALF(I,K)*ALF(I,K) ALF1(I,K)=1.-ALF(I,K) ALF1Q(I,K)=ALF1(I,K)*ALF1(I,K) ALF2(I,K)=ALF1(I,K)-ALF(I,K) ALF3(I,K)=ALF1(I,K)*ALF(I,K) C 320 CONTINUE 32 CONTINUE c print*,'ap ADVYP 32' C DO 33 JV=1,NTRA DO 33 K=1,LAT-1 KP=K+1 DO 330 I=1,LON C IF(VGRI(I,K,L).LT.0.) THEN C TEMPTM=-ALF(I,K)*S0(I,K,L,JV)+ALF1(I,K)*F0(I,K,JV) S0 (I,K,L,JV)=S0(I,K,L,JV)+F0(I,K,JV) SYY(I,K,L,JV)=ALFQ(I,K)*FYY(I,K,JV)+ALF1Q(I,K)*SYY(I,K,L,JV) + +5.*( ALF3(I,K)*(FY(I,K,JV)-SY(I,K,L,JV))+ALF2(I,K)*TEMPTM ) SY (I,K,L,JV)=ALF(I,K)*FY(I,K,JV)+ALF1(I,K)*SY(I,K,L,JV) + +3.*TEMPTM SSXY(I,K,L,JV)=ALF (I,K)*FXY(I,K,JV)+ALF1(I,K)*SSXY(I,K,L,JV) + +3.*(ALF1(I,K)*FX (I,K,JV)-ALF (I,K)*SSX (I,K,L,JV)) SYZ(I,K,L,JV)=ALF (I,K)*FYZ(I,K,JV)+ALF1(I,K)*SYZ(I,K,L,JV) + +3.*(ALF1(I,K)*FZ (I,K,JV)-ALF (I,K)*SZ (I,K,L,JV)) SSX (I,K,L,JV)=SSX (I,K,L,JV)+FX (I,K,JV) SZ (I,K,L,JV)=SZ (I,K,L,JV)+FZ (I,K,JV) SSXX(I,K,L,JV)=SSXX(I,K,L,JV)+FXX(I,K,JV) SSXZ(I,K,L,JV)=SSXZ(I,K,L,JV)+FXZ(I,K,JV) SZZ(I,K,L,JV)=SZZ(I,K,L,JV)+FZZ(I,K,JV) C ELSE C TEMPTM=ALF(I,K)*S0(I,KP,L,JV)-ALF1(I,K)*F0(I,K,JV) S0 (I,KP,L,JV)=S0(I,KP,L,JV)+F0(I,K,JV) SYY(I,KP,L,JV)=ALFQ(I,K)*FYY(I,K,JV)+ALF1Q(I,K)*SYY(I,KP,L,JV) + +5.*( ALF3(I,K)*(SY(I,KP,L,JV)-FY(I,K,JV))-ALF2(I,K)*TEMPTM ) SY (I,KP,L,JV)=ALF(I,K)*FY(I,K,JV)+ALF1(I,K)*SY(I,KP,L,JV) + +3.*TEMPTM SSXY(I,KP,L,JV)=ALF(I,K)*FXY(I,K,JV)+ALF1(I,K)*SSXY(I,KP,L,JV) + +3.*(ALF(I,K)*SSX(I,KP,L,JV)-ALF1(I,K)*FX(I,K,JV)) SYZ(I,KP,L,JV)=ALF(I,K)*FYZ(I,K,JV)+ALF1(I,K)*SYZ(I,KP,L,JV) + +3.*(ALF(I,K)*SZ(I,KP,L,JV)-ALF1(I,K)*FZ(I,K,JV)) SSX (I,KP,L,JV)=SSX (I,KP,L,JV)+FX (I,K,JV) SZ (I,KP,L,JV)=SZ (I,KP,L,JV)+FZ (I,K,JV) SSXX(I,KP,L,JV)=SSXX(I,KP,L,JV)+FXX(I,K,JV) SSXZ(I,KP,L,JV)=SSXZ(I,KP,L,JV)+FXZ(I,K,JV) SZZ(I,KP,L,JV)=SZZ(I,KP,L,JV)+FZZ(I,K,JV) C ENDIF C 330 CONTINUE 33 CONTINUE c print*,'ap ADVYP 33' C C traitement special pour le pole Sud (idem pole Nord) C K=LAT C SM0=0. DO 40 JV=1,NTRA S00(JV)=0. 40 CONTINUE C DO 41 I=1,LON C IF(VGRI(I,K,L).GE.0.) THEN FM(I,K)=VGRI(I,K,L)*DTY ALF(I,K)=FM(I,K)/SM(I,K,L) SM(I,K,L)=SM(I,K,L)-FM(I,K) SM0=SM0+FM(I,K) ENDIF C ALFQ(I,K)=ALF(I,K)*ALF(I,K) ALF1(I,K)=1.-ALF(I,K) ALF1Q(I,K)=ALF1(I,K)*ALF1(I,K) ALF2(I,K)=ALF1(I,K)-ALF(I,K) ALF3(I,K)=ALF(I,K)*ALFQ(I,K) ALF4(I,K)=ALF1(I,K)*ALF1Q(I,K) C 41 CONTINUE c print*,'ap ADVYP 41' C DO 42 JV=1,NTRA DO 420 I=1,LON C IF(VGRI(I,K,L).GE.0.) THEN F0 (I,K,JV)=ALF(I,K)* ( S0(I,K,L,JV)+ALF1(I,K)* + ( SY(I,K,L,JV)+ALF2(I,K)*SYY(I,K,L,JV) ) ) S00(JV)=S00(JV)+F0(I,K,JV) C S0 (I,K,L,JV)=S0 (I,K,L,JV)-F0 (I,K,JV) SY (I,K,L,JV)=ALF1Q(I,K)* + (SY(I,K,L,JV)-3.*ALF(I,K)*SYY(I,K,L,JV)) SYY(I,K,L,JV)=ALF4 (I,K)*SYY(I,K,L,JV) SSX (I,K,L,JV)=ALF1(I,K)*(SSX(I,K,L,JV)-ALF(I,K)*SSXY(I,K,L,JV)) SZ (I,K,L,JV)=ALF1(I,K)*(SZ(I,K,L,JV)-ALF(I,K)*SYZ(I,K,L,JV)) SSXX(I,K,L,JV)=ALF1 (I,K)*SSXX(I,K,L,JV) SSXZ(I,K,L,JV)=ALF1 (I,K)*SSXZ(I,K,L,JV) SZZ(I,K,L,JV)=ALF1 (I,K)*SZZ(I,K,L,JV) SSXY(I,K,L,JV)=ALF1Q(I,K)*SSXY(I,K,L,JV) SYZ(I,K,L,JV)=ALF1Q(I,K)*SYZ(I,K,L,JV) ENDIF C 420 CONTINUE 42 CONTINUE c print*,'ap ADVYP 42' C DO 43 I=1,LON IF(VGRI(I,K,L).LT.0.) THEN FM(I,K)=-VGRI(I,K,L)*DTY ALF(I,K)=FM(I,K)/SM0 ENDIF 43 CONTINUE c print*,'ap ADVYP 43' C DO 44 JV=1,NTRA DO 440 I=1,LON IF(VGRI(I,K,L).LT.0.) THEN F0(I,K,JV)=ALF(I,K)*S00(JV) ENDIF 440 CONTINUE 44 CONTINUE C C puts the temporary moments Fi into appropriate neighboring boxes C DO 45 I=1,LON C IF(VGRI(I,K,L).LT.0.) THEN SM(I,K,L)=SM(I,K,L)+FM(I,K) ALF(I,K)=FM(I,K)/SM(I,K,L) ENDIF C ALFQ(I,K)=ALF(I,K)*ALF(I,K) ALF1(I,K)=1.-ALF(I,K) ALF1Q(I,K)=ALF1(I,K)*ALF1(I,K) ALF2(I,K)=ALF1(I,K)-ALF(I,K) ALF3(I,K)=ALF1(I,K)*ALF(I,K) C 45 CONTINUE c print*,'ap ADVYP 45' C DO 46 JV=1,NTRA DO 460 I=1,LON C IF(VGRI(I,K,L).LT.0.) THEN C TEMPTM=-ALF(I,K)*S0(I,K,L,JV)+ALF1(I,K)*F0(I,K,JV) S0 (I,K,L,JV)=S0(I,K,L,JV)+F0(I,K,JV) SYY(I,K,L,JV)=ALF1Q(I,K)*SYY(I,K,L,JV) + +5.*(-ALF3 (I,K)*SY (I,K,L,JV)+ALF2(I,K)*TEMPTM ) SY (I,K,L,JV)=ALF1(I,K)*SY (I,K,L,JV)+3.*TEMPTM SSXY(I,K,L,JV)=ALF1(I,K)*SSXY(I,K,L,JV)-3.*ALF(I,K)*SSX(I,K,L,JV) SYZ(I,K,L,JV)=ALF1(I,K)*SYZ(I,K,L,JV)-3.*ALF(I,K)*SZ(I,K,L,JV) C ENDIF C 460 CONTINUE 46 CONTINUE c print*,'ap ADVYP 46' C 1 CONTINUE c-------------------------------------------------- C bouclage cyclique horizontal . DO l = 1,llm DO jv = 1,ntra DO j = 1,jjp1 SM(iip1,j,l) = SM(1,j,l) S0(iip1,j,l,jv) = S0(1,j,l,jv) SSX(iip1,j,l,jv) = SSX(1,j,l,jv) SY(iip1,j,l,jv) = SY(1,j,l,jv) SZ(iip1,j,l,jv) = SZ(1,j,l,jv) END DO END DO END DO c ------------------------------------------------------------------- C *** Test negativite: c DO jv = 1,ntra c DO l = 1,llm c DO j = 1,jjp1 c DO i = 1,iip1 c IF (s0( i,j,l,jv ).lt.0.) THEN c PRINT*, '------ S0 < 0 en FIN ADVYP ---' c PRINT*, 'S0(',i,j,l,jv,')=', S0(i,j,l,jv) cc STOP c ENDIF c ENDDO c ENDDO c ENDDO c ENDDO c ------------------------------------------------------------------- C *** Test : diag de la qtite totale de traceur dans C l'atmosphere avant l'advection en Y DO l = 1,llm DO j = 1,jjp1 DO i = 1,iim sqf = sqf + S0(i,j,l,ntra) END DO END DO END DO PRINT*,'---------- DIAG DANS ADVY - SORTIE --------' PRINT*,'sqf=',sqf c print*,'ap ADVYP fin' c----------------------------------------------------------------- C RETURN END