source: LMDZ6/branches/Amaury_dev/libf/dyn3d_common/advyp.f90

! $Header$

SUBROUTINE ADVYP(LIMIT, DTY, PBARV, SM, S0, SSX, SY, SZ &
        , SSXX, SSXY, SSXZ, SYY, SYZ, SZZ, ntra)
  USE lmdz_comgeom

  USE lmdz_dimensions, ONLY: iim, jjm, llm, ndm
  USE lmdz_paramet
  IMPLICIT NONE
  !CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
  !                                                                 C
  !  second-order moments (SOM) advection of tracer in Y direction  C
  !                                                                 C
  !CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
  ! C
  !  Source : Pascal Simon ( Meteo, CNRM )                         C
  !  Adaptation : A.A. (LGGE)                                      C
  !  Derniere Modif : 19/10/95 LAST
  ! C
  !  sont les arguments d'entree pour le s-pg                      C
  !                                                                C
  !  argument de sortie du s-pg                                    C
  !                                                                C
  !CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC
  !CCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCCC

  !  Rem : Probleme aux poles il faut reecrire ce cas specifique
  !    Attention au sens de l'indexation

  !  parametres principaux du modele

  !



  !  Arguments :
  !  ----------
  !  dty : frequence fictive d'appel du transport
  !  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
  ! PARAMETER (ntra = 1)

  REAL :: dty
  REAL :: pbarv (iip1, jjm, llm)

  !  moments: SM  total mass in each grid box
  ! S0  mass of tracer in each grid box
  ! Si  1rst order moment in i direction

  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)

  !  Local :
  !  -------

  !  mass fluxes across the boundaries (UGRI,VGRI,WGRI)
  !  mass fluxes in kg
  !  declaration :

  REAL :: VGRI(iip1, 0:jjp1, llm)

  !  Rem : UGRI et WGRI ne sont pas utilises dans
  !  cette SUBROUTINE ( advection en y uniquement )
  !  Rem 2 :le dimensionnement de VGRI depend de celui de pbarv

  !  the moments F are similarly defined and used as temporary
  !  storage for portions of the grid boxes in transit

  !  the moments Fij are used as temporary storage for
  !  portions of the grid boxes in transit at the current level

  !  work arrays


  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

  !  work arrays

  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

  !  Special pour poles

  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 :: 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

  !-----------------------------------------------------------------
  ! initialisations

  sbms = 0.
  sfms = 0.
  sfzs = 0.
  sbmn = 0.
  sfmn = 0.
  sfzn = 0.

  !-----------------------------------------------------------------
  ! *** Test : diag de la qtite totale de traceur dans
  ! l'atmosphere avant l'advection en Y

  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

  !-----------------------------------------------------------------
  !  Interface : adaptation nouveau modele
  !  -------------------------------------

  !  Conversion des flux de masses en kg
  !-AA 20/10/94  le signe -1 est necessaire car indexation opposee

  DO l = 1, llm
    DO j = 1, jjm
      DO i = 1, iip1
        vgri (i, j, llm + 1 - l) = -1. * pbarv (i, j, l)
      END DO
    END DO
  END DO

  !AA 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

  !----------------- START HERE -----------------------
  !  boucle sur les niveaux

  DO L = 1, NIV

    !  place limits on appropriate moments before transport
    !  (if flux-limiting is to be applied)

    IF(.NOT.LIMIT) GO TO 11

    DO JV = 1, NTRA
      DO K = 1, LAT
        DO I = 1, LON
          IF(S0(I, K, L, JV)>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
        END DO
      END DO
    END DO

    11   CONTINUE

    !  le flux a travers le pole Nord est traite separement

    SM0 = 0.
    DO JV = 1, NTRA
      S00(JV) = 0.
    END DO

    DO I = 1, LON

      IF(VGRI(I, 0, L)<=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

      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)

    END DO
    ! PRINT*,'ADVYP 21'

    DO JV = 1, NTRA
      DO I = 1, LON

        IF(VGRI(I, 0, L)<=0.) THEN

          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)))

          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)

        ENDIF

      END DO
    END DO

    DO I = 1, LON
      IF(VGRI(I, 0, L)>0.) THEN
        FM(I, 0) = VGRI(I, 0, L) * DTY
        ALF(I, 0) = FM(I, 0) / SM0
      ENDIF
    END DO

    DO JV = 1, NTRA
      DO I = 1, LON
        IF(VGRI(I, 0, L)>0.) THEN
          F0(I, 0, JV) = ALF(I, 0) * S00(JV)
        ENDIF
      END DO
    END DO

    !  puts the temporary moments Fi into appropriate neighboring boxes

    ! PRINT*,'av ADVYP 25'
    DO I = 1, LON

      IF(VGRI(I, 0, L)>0.) THEN
        SM(I, 1, L) = SM(I, 1, L) + FM(I, 0)
        ALF(I, 0) = FM(I, 0) / SM(I, 1, L)
      ENDIF

      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)

    END DO
    ! PRINT*,'av ADVYP 25'

    DO JV = 1, NTRA
      DO I = 1, LON

        IF(VGRI(I, 0, L)>0.) THEN

          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)

        ENDIF

      END DO
    END DO

    !  calculate flux and moments between adjacent boxes
    !  1- create temporary moments/masses for partial boxes in transit
    !  2- reajusts moments remaining in the box

    !  flux from KP to K if V(K).lt.0 and from K to KP if V(K).gt.0

    ! PRINT*,'av ADVYP 30'
    DO K = 1, LAT - 1
      KP = K + 1
      DO I = 1, LON

        IF(VGRI(I, K, L)<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

        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)

      END DO
    END DO
    ! PRINT*,'ap ADVYP 30'

    DO JV = 1, NTRA
      DO K = 1, LAT - 1
        KP = K + 1
        DO I = 1, LON

          IF(VGRI(I, K, L)<0.) THEN

            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)

            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)

          ELSE

            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)

            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)

          ENDIF

        END DO
      END DO
    END DO
    ! PRINT*,'ap ADVYP 31'

    !  puts the temporary moments Fi into appropriate neighboring boxes

    DO K = 1, LAT - 1
      KP = K + 1
      DO I = 1, LON

        IF(VGRI(I, K, L)<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

        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)

      END DO
    END DO
    ! PRINT*,'ap ADVYP 32'

    DO JV = 1, NTRA
      DO K = 1, LAT - 1
        KP = K + 1
        DO I = 1, LON

          IF(VGRI(I, K, L)<0.) THEN

            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)

          ELSE

            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)

          ENDIF

        END DO
      END DO
    END DO
    ! PRINT*,'ap ADVYP 33'

    !  traitement special pour le pole Sud (idem pole Nord)

    K = LAT

    SM0 = 0.
    DO JV = 1, NTRA
      S00(JV) = 0.
    END DO

    DO I = 1, LON

      IF(VGRI(I, K, L)>=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

      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)

    END DO
    ! PRINT*,'ap ADVYP 41'

    DO JV = 1, NTRA
      DO I = 1, LON

        IF(VGRI(I, K, L)>=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)

          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

      END DO
    END DO
    ! PRINT*,'ap ADVYP 42'

    DO I = 1, LON
      IF(VGRI(I, K, L)<0.) THEN
        FM(I, K) = -VGRI(I, K, L) * DTY
        ALF(I, K) = FM(I, K) / SM0
      ENDIF
    END DO
    ! PRINT*,'ap ADVYP 43'

    DO JV = 1, NTRA
      DO I = 1, LON
        IF(VGRI(I, K, L)<0.) THEN
          F0(I, K, JV) = ALF(I, K) * S00(JV)
        ENDIF
      END DO
    END DO

    !  puts the temporary moments Fi into appropriate neighboring boxes

    DO I = 1, LON

      IF(VGRI(I, K, L)<0.) THEN
        SM(I, K, L) = SM(I, K, L) + FM(I, K)
        ALF(I, K) = FM(I, K) / SM(I, K, L)
      ENDIF

      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)

    END DO
    ! PRINT*,'ap ADVYP 45'

    DO JV = 1, NTRA
      DO I = 1, LON

        IF(VGRI(I, K, L)<0.) THEN

          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)

        ENDIF

      END DO
    END DO
    ! PRINT*,'ap ADVYP 46'

  END DO

  !--------------------------------------------------
  ! 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

  ! -------------------------------------------------------------------
  ! *** Test  negativite:

  ! DO jv = 1,ntra
  !  DO l = 1,llm
  !    DO j = 1,jjp1
  !      DO i = 1,iip1
  !         IF (s0( i,j,l,jv ).lt.0.) THEN
  !            PRINT*, '------ S0 < 0 en FIN ADVYP ---'
  !            PRINT*, 'S0(',i,j,l,jv,')=', S0(i,j,l,jv)
  !c                 STOP
  !         ENDIF
  !      ENDDO
  !    ENDDO
  !  ENDDO
  ! ENDDO


  ! -------------------------------------------------------------------
  ! *** Test : diag de la qtite totale de traceur dans
  !       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
  ! PRINT*,'ap ADVYP fin'

  !-----------------------------------------------------------------

  RETURN
END SUBROUTINE ADVYP