source: LMDZ6/trunk/libf/phylmd/orografi.f90 @ 5319

! $Id: orografi.f90 5309 2024-11-01 11:39:44Z fairhead $

SUBROUTINE drag_noro(nlon, nlev, dtime, paprs, pplay, pmea, pstd, psig, pgam, &
    pthe, ppic, pval, kgwd, kdx, ktest, t, u, v, pulow, pvlow, pustr, pvstr, &
    d_t, d_u, d_v)

  USE dimphy
  USE yomcst_mod_h
IMPLICIT NONE
  ! ======================================================================
  ! Auteur(s): F.Lott (LMD/CNRS) date: 19950201
  ! Objet: Frottement de la montagne Interface
  ! ======================================================================
  ! Arguments:
  ! dtime---input-R- pas d'integration (s)
  ! paprs---input-R-pression pour chaque inter-couche (en Pa)
  ! pplay---input-R-pression pour le mileu de chaque couche (en Pa)
  ! t-------input-R-temperature (K)
  ! u-------input-R-vitesse horizontale (m/s)
  ! v-------input-R-vitesse horizontale (m/s)

  ! d_t-----output-R-increment de la temperature
  ! d_u-----output-R-increment de la vitesse u
  ! d_v-----output-R-increment de la vitesse v
  ! ======================================================================


  ! ARGUMENTS

  INTEGER nlon, nlev
  REAL dtime
  REAL paprs(klon, klev+1)
  REAL pplay(klon, klev)
  REAL pmea(nlon), pstd(nlon), psig(nlon), pgam(nlon), pthe(nlon)
  REAL ppic(nlon), pval(nlon)
  REAL pulow(nlon), pvlow(nlon), pustr(nlon), pvstr(nlon)
  REAL t(nlon, nlev), u(nlon, nlev), v(nlon, nlev)
  REAL d_t(nlon, nlev), d_u(nlon, nlev), d_v(nlon, nlev)

  INTEGER i, k, kgwd, kdx(nlon), ktest(nlon)

  ! Variables locales:

  REAL zgeom(klon, klev)
  REAL pdtdt(klon, klev), pdudt(klon, klev), pdvdt(klon, klev)
  REAL pt(klon, klev), pu(klon, klev), pv(klon, klev)
  REAL papmf(klon, klev), papmh(klon, klev+1)

  ! initialiser les variables de sortie (pour securite)

  DO i = 1, klon
    pulow(i) = 0.0
    pvlow(i) = 0.0
    pustr(i) = 0.0
    pvstr(i) = 0.0
  END DO
  DO k = 1, klev
    DO i = 1, klon
      d_t(i, k) = 0.0
      d_u(i, k) = 0.0
      d_v(i, k) = 0.0
      pdudt(i, k) = 0.0
      pdvdt(i, k) = 0.0
      pdtdt(i, k) = 0.0
    END DO
  END DO

  ! preparer les variables d'entree (attention: l'ordre des niveaux
  ! verticaux augmente du haut vers le bas)

  DO k = 1, klev
    DO i = 1, klon
      pt(i, k) = t(i, klev-k+1)
      pu(i, k) = u(i, klev-k+1)
      pv(i, k) = v(i, klev-k+1)
      papmf(i, k) = pplay(i, klev-k+1)
    END DO
  END DO
  DO k = 1, klev + 1
    DO i = 1, klon
      papmh(i, k) = paprs(i, klev-k+2)
    END DO
  END DO
  DO i = 1, klon
    zgeom(i, klev) = rd*pt(i, klev)*log(papmh(i,klev+1)/papmf(i,klev))
  END DO
  DO k = klev - 1, 1, -1
    DO i = 1, klon
      zgeom(i, k) = zgeom(i, k+1) + rd*(pt(i,k)+pt(i,k+1))/2.0*log(papmf(i,k+ &
        1)/papmf(i,k))
    END DO
  END DO

  ! appeler la routine principale

  CALL orodrag(klon, klev, kgwd, kdx, ktest, dtime, papmh, papmf, zgeom, pt, &
    pu, pv, pmea, pstd, psig, pgam, pthe, ppic, pval, pulow, pvlow, pdudt, &
    pdvdt, pdtdt)

  DO k = 1, klev
    DO i = 1, klon
      d_u(i, klev+1-k) = dtime*pdudt(i, k)
      d_v(i, klev+1-k) = dtime*pdvdt(i, k)
      d_t(i, klev+1-k) = dtime*pdtdt(i, k)
      pustr(i) = pustr(i) &        ! IM BUG  .
                                   ! +rg*pdudt(i,k)*(papmh(i,k+1)-papmh(i,k))
        +pdudt(i, k)*(papmh(i,k+1)-papmh(i,k))/rg
      pvstr(i) = pvstr(i) &        ! IM BUG  .
                                   ! +rg*pdvdt(i,k)*(papmh(i,k+1)-papmh(i,k))
        +pdvdt(i, k)*(papmh(i,k+1)-papmh(i,k))/rg
    END DO
  END DO

  RETURN
END SUBROUTINE drag_noro
SUBROUTINE orodrag(nlon, nlev, kgwd, kdx, ktest, ptsphy, paphm1, papm1, &
    pgeom1, ptm1, pum1, pvm1, pmea, pstd, psig, pgamma, ptheta, ppic, pval &
  ! outputs
    , pulow, pvlow, pvom, pvol, pte)

  USE yomcst_mod_h
  USE dimphy
  USE yoegwd_mod_h
  IMPLICIT NONE



  ! **** *gwdrag* - does the gravity wave parametrization.

  ! purpose.
  ! --------

  ! this routine computes the physical tendencies of the
  ! prognostic variables u,v  and t due to  vertical transports by
  ! subgridscale orographically excited gravity waves

  ! **   interface.
  ! ----------
  ! called from *callpar*.

  ! the routine takes its input from the long-term storage:
  ! u,v,t and p at t-1.

  ! explicit arguments :
  ! --------------------
  ! ==== inputs ===
  ! ==== outputs ===

  ! implicit arguments :   none
  ! --------------------

  ! implicit logical (l)

  ! method.
  ! -------

  ! externals.
  ! ----------
  INTEGER ismin, ismax
  EXTERNAL ismin, ismax

  ! reference.
  ! ----------

  ! author.
  ! -------
  ! m.miller + b.ritter   e.c.m.w.f.     15/06/86.

  ! f.lott + m. miller    e.c.m.w.f.     22/11/94
  ! -----------------------------------------------------------------------

  ! *       0.1   arguments
  ! ---------


  ! ym      integer nlon, nlev, klevm1
  INTEGER nlon, nlev
  INTEGER kgwd, jl, ilevp1, jk, ji
  REAL zdelp, ztemp, zforc, ztend
  REAL rover, zb, zc, zconb, zabsv
  REAL zzd1, ratio, zbet, zust, zvst, zdis
  REAL pte(nlon, nlev), pvol(nlon, nlev), pvom(nlon, nlev), pulow(klon), &
    pvlow(klon)
  REAL pum1(nlon, nlev), pvm1(nlon, nlev), ptm1(nlon, nlev), pmea(nlon), &
    pstd(nlon), psig(nlon), pgamma(nlon), ptheta(nlon), ppic(nlon), &
    pval(nlon), pgeom1(nlon, nlev), papm1(nlon, nlev), paphm1(nlon, nlev+1)

  INTEGER kdx(nlon), ktest(nlon)
  ! -----------------------------------------------------------------------

  ! *       0.2   local arrays
  ! ------------
  INTEGER isect(klon), icrit(klon), ikcrith(klon), ikenvh(klon), iknu(klon), &
    iknu2(klon), ikcrit(klon), ikhlim(klon)

  REAL ztau(klon, klev+1), ztauf(klon, klev+1), zstab(klon, klev+1), &
    zvph(klon, klev+1), zrho(klon, klev+1), zri(klon, klev+1), &
    zpsi(klon, klev+1), zzdep(klon, klev)
  REAL zdudt(klon), zdvdt(klon), zdtdt(klon), zdedt(klon), zvidis(klon), &
    znu(klon), zd1(klon), zd2(klon), zdmod(klon)
  REAL ztmst, ptsphy, zrtmst

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

  ! *         1.    initialization
  ! --------------


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

  ! *         1.1   computational constants
  ! -----------------------


  ! ztmst=twodt
  ! if(nstep.eq.nstart) ztmst=0.5*twodt
  ! ym      klevm1=klev-1
  ztmst = ptsphy
  zrtmst = 1./ztmst

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

  ! *         1.3   check whether row contains point for printing
  ! ---------------------------------------------


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

  ! *         2.     precompute basic state variables.
  ! *                ---------- ----- ----- ----------
  ! *                define low level wind, project winds in plane of
  ! *                low level wind, determine sector in which to take
  ! *                the variance and set indicator for critical levels.




  CALL orosetup(nlon, ktest, ikcrit, ikcrith, icrit, ikenvh, iknu, iknu2, &
    paphm1, papm1, pum1, pvm1, ptm1, pgeom1, pstd, zrho, zri, zstab, ztau, &
    zvph, zpsi, zzdep, pulow, pvlow, ptheta, pgamma, pmea, ppic, pval, znu, &
    zd1, zd2, zdmod)

  ! ***********************************************************


  ! *         3.      compute low level stresses using subcritical and
  ! *                 supercritical forms.computes anisotropy coefficient
  ! *                 as measure of orographic twodimensionality.


  CALL gwstress(nlon, nlev, ktest, icrit, ikenvh, iknu, zrho, zstab, zvph, &
    pstd, psig, pmea, ppic, ztau, pgeom1, zdmod)

  ! *         4.      compute stress profile.
  ! *                 ------- ------ --------



  CALL gwprofil(nlon, nlev, kgwd, kdx, ktest, ikcrith, icrit, paphm1, zrho, &
    zstab, zvph, zri, ztau, zdmod, psig, pstd)

  ! *         5.      compute tendencies.
  ! *                 -------------------


  ! explicit solution at all levels for the gravity wave
  ! implicit solution for the blocked levels

  DO jl = kidia, kfdia
    zvidis(jl) = 0.0
    zdudt(jl) = 0.0
    zdvdt(jl) = 0.0
    zdtdt(jl) = 0.0
  END DO

  ilevp1 = klev + 1


  DO jk = 1, klev


    ! do 523 jl=1,kgwd
    ! ji=kdx(jl)
    ! Modif vectorisation 02/04/2004
    DO ji = kidia, kfdia
      IF (ktest(ji)==1) THEN

        zdelp = paphm1(ji, jk+1) - paphm1(ji, jk)
        ztemp = -rg*(ztau(ji,jk+1)-ztau(ji,jk))/(zvph(ji,ilevp1)*zdelp)
        zdudt(ji) = (pulow(ji)*zd1(ji)-pvlow(ji)*zd2(ji))*ztemp/zdmod(ji)
        zdvdt(ji) = (pvlow(ji)*zd1(ji)+pulow(ji)*zd2(ji))*ztemp/zdmod(ji)

        ! controle des overshoots:

        zforc = sqrt(zdudt(ji)**2+zdvdt(ji)**2) + 1.E-12
        ztend = sqrt(pum1(ji,jk)**2+pvm1(ji,jk)**2)/ztmst + 1.E-12
        rover = 0.25
        IF (zforc>=rover*ztend) THEN
          zdudt(ji) = rover*ztend/zforc*zdudt(ji)
          zdvdt(ji) = rover*ztend/zforc*zdvdt(ji)
        END IF

        ! fin du controle des overshoots

        IF (jk>=ikenvh(ji)) THEN
          zb = 1.0 - 0.18*pgamma(ji) - 0.04*pgamma(ji)**2
          zc = 0.48*pgamma(ji) + 0.3*pgamma(ji)**2
          zconb = 2.*ztmst*gkwake*psig(ji)/(4.*pstd(ji))
          zabsv = sqrt(pum1(ji,jk)**2+pvm1(ji,jk)**2)/2.
          zzd1 = zb*cos(zpsi(ji,jk))**2 + zc*sin(zpsi(ji,jk))**2
          ratio = (cos(zpsi(ji,jk))**2+pgamma(ji)*sin(zpsi(ji, &
            jk))**2)/(pgamma(ji)*cos(zpsi(ji,jk))**2+sin(zpsi(ji,jk))**2)
          zbet = max(0., 2.-1./ratio)*zconb*zzdep(ji, jk)*zzd1*zabsv

          ! simplement oppose au vent

          zdudt(ji) = -pum1(ji, jk)/ztmst
          zdvdt(ji) = -pvm1(ji, jk)/ztmst

          ! projection dans la direction de l'axe principal de l'orographie
          ! mod     zdudt(ji)=-(pum1(ji,jk)*cos(ptheta(ji)*rpi/180.)
          ! mod *              +pvm1(ji,jk)*sin(ptheta(ji)*rpi/180.))
          ! mod *              *cos(ptheta(ji)*rpi/180.)/ztmst
          ! mod     zdvdt(ji)=-(pum1(ji,jk)*cos(ptheta(ji)*rpi/180.)
          ! mod *              +pvm1(ji,jk)*sin(ptheta(ji)*rpi/180.))
          ! mod *              *sin(ptheta(ji)*rpi/180.)/ztmst
          zdudt(ji) = zdudt(ji)*(zbet/(1.+zbet))
          zdvdt(ji) = zdvdt(ji)*(zbet/(1.+zbet))
        END IF
        pvom(ji, jk) = zdudt(ji)
        pvol(ji, jk) = zdvdt(ji)
        zust = pum1(ji, jk) + ztmst*zdudt(ji)
        zvst = pvm1(ji, jk) + ztmst*zdvdt(ji)
        zdis = 0.5*(pum1(ji,jk)**2+pvm1(ji,jk)**2-zust**2-zvst**2)
        zdedt(ji) = zdis/ztmst
        zvidis(ji) = zvidis(ji) + zdis*zdelp
        zdtdt(ji) = zdedt(ji)/rcpd
        ! pte(ji,jk)=zdtdt(ji)

        ! ENCORE UN TRUC POUR EVITER LES EXPLOSIONS

        pte(ji, jk) = 0.0

      END IF
    END DO

  END DO


  RETURN
END SUBROUTINE orodrag
SUBROUTINE orosetup(nlon, ktest, kkcrit, kkcrith, kcrit, kkenvh, kknu, kknu2, &
    paphm1, papm1, pum1, pvm1, ptm1, pgeom1, pstd, prho, pri, pstab, ptau, &
    pvph, ppsi, pzdep, pulow, pvlow, ptheta, pgamma, pmea, ppic, pval, pnu, &
    pd1, pd2, pdmod)

  ! **** *gwsetup*

  ! purpose.
  ! --------

  ! **   interface.
  ! ----------
  ! from *orodrag*

  ! explicit arguments :
  ! --------------------
  ! ==== inputs ===
  ! ==== outputs ===

  ! implicit arguments :   none
  ! --------------------

  ! method.
  ! -------


  ! externals.
  ! ----------


  ! reference.
  ! ----------

  ! see ecmwf research department documentation of the "i.f.s."

  ! author.
  ! -------

  ! modifications.
  ! --------------
  ! f.lott  for the new-gwdrag scheme november 1993

  ! -----------------------------------------------------------------------
USE yoegwd_mod_h
    USE dimphy
  USE yomcst_mod_h
IMPLICIT NONE




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

  ! *       0.1   arguments
  ! ---------

  INTEGER nlon
  INTEGER jl, jk
  REAL zdelp

  INTEGER kkcrit(nlon), kkcrith(nlon), kcrit(nlon), ktest(nlon), kkenvh(nlon)


  REAL paphm1(nlon, klev+1), papm1(nlon, klev), pum1(nlon, klev), &
    pvm1(nlon, klev), ptm1(nlon, klev), pgeom1(nlon, klev), &
    prho(nlon, klev+1), pri(nlon, klev+1), pstab(nlon, klev+1), &
    ptau(nlon, klev+1), pvph(nlon, klev+1), ppsi(nlon, klev+1), &
    pzdep(nlon, klev)
  REAL pulow(nlon), pvlow(nlon), ptheta(nlon), pgamma(nlon), pnu(nlon), &
    pd1(nlon), pd2(nlon), pdmod(nlon)
  REAL pstd(nlon), pmea(nlon), ppic(nlon), pval(nlon)

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

  ! *       0.2   local arrays
  ! ------------


  INTEGER ilevm1, ilevm2, ilevh
  REAL zcons1, zcons2, zcons3, zhgeo
  REAL zu, zphi, zvt1, zvt2, zst, zvar, zdwind, zwind
  REAL zstabm, zstabp, zrhom, zrhop, alpha
  REAL zggeenv, zggeom1, zgvar
  LOGICAL lo
  LOGICAL ll1(klon, klev+1)
  INTEGER kknu(klon), kknu2(klon), kknub(klon), kknul(klon), kentp(klon), &
    ncount(klon)

  REAL zhcrit(klon, klev), zvpf(klon, klev), zdp(klon, klev)
  REAL znorm(klon), zb(klon), zc(klon), zulow(klon), zvlow(klon), znup(klon), &
    znum(klon)

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

  ! *         1.    initialization
  ! --------------

  ! print *,' entree gwsetup'

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

  ! *         1.1   computational constants
  ! -----------------------


  ilevm1 = klev - 1
  ilevm2 = klev - 2
  ilevh = klev/3

  zcons1 = 1./rd
  ! old  zcons2=g**2/cpd
  zcons2 = rg**2/rcpd
  ! old  zcons3=1.5*api
  zcons3 = 1.5*rpi

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

  ! *         2.
  ! --------------


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

  ! *         2.1     define low level wind, project winds in plane of
  ! *                 low level wind, determine sector in which to take
  ! *                 the variance and set indicator for critical levels.



  DO jl = kidia, kfdia
    kknu(jl) = klev
    kknu2(jl) = klev
    kknub(jl) = klev
    kknul(jl) = klev
    pgamma(jl) = max(pgamma(jl), gtsec)
    ll1(jl, klev+1) = .FALSE.
  END DO

  ! Ajouter une initialisation (L. Li, le 23fev99):

  DO jk = klev, ilevh, -1
    DO jl = kidia, kfdia
      ll1(jl, jk) = .FALSE.
    END DO
  END DO

  ! *      define top of low level flow
  ! ----------------------------
  DO jk = klev, ilevh, -1
    DO jl = kidia, kfdia
      lo = (paphm1(jl,jk)/paphm1(jl,klev+1)) >= gsigcr
      IF (lo) THEN
        kkcrit(jl) = jk
      END IF
      zhcrit(jl, jk) = ppic(jl)
      zhgeo = pgeom1(jl, jk)/rg
      ll1(jl, jk) = (zhgeo>zhcrit(jl,jk))
      IF (ll1(jl,jk) .NEQV. ll1(jl,jk+1)) THEN
        kknu(jl) = jk
      END IF
      IF (.NOT. ll1(jl,ilevh)) kknu(jl) = ilevh
    END DO
  END DO
  DO jk = klev, ilevh, -1
    DO jl = kidia, kfdia
      zhcrit(jl, jk) = ppic(jl) - pval(jl)
      zhgeo = pgeom1(jl, jk)/rg
      ll1(jl, jk) = (zhgeo>zhcrit(jl,jk))
      IF (ll1(jl,jk) .NEQV. ll1(jl,jk+1)) THEN
        kknu2(jl) = jk
      END IF
      IF (.NOT. ll1(jl,ilevh)) kknu2(jl) = ilevh
    END DO
  END DO
  DO jk = klev, ilevh, -1
    DO jl = kidia, kfdia
      zhcrit(jl, jk) = amax1(ppic(jl)-pmea(jl), pmea(jl)-pval(jl))
      zhgeo = pgeom1(jl, jk)/rg
      ll1(jl, jk) = (zhgeo>zhcrit(jl,jk))
      IF (ll1(jl,jk) .NEQV. ll1(jl,jk+1)) THEN
        kknub(jl) = jk
      END IF
      IF (.NOT. ll1(jl,ilevh)) kknub(jl) = ilevh
    END DO
  END DO

  DO jl = kidia, kfdia
    kknu(jl) = min(kknu(jl), nktopg)
    kknu2(jl) = min(kknu2(jl), nktopg)
    kknub(jl) = min(kknub(jl), nktopg)
    kknul(jl) = klev
  END DO

  ! c*     initialize various arrays

  DO jl = kidia, kfdia
    prho(jl, klev+1) = 0.0
    pstab(jl, klev+1) = 0.0
    pstab(jl, 1) = 0.0
    pri(jl, klev+1) = 9999.0
    ppsi(jl, klev+1) = 0.0
    pri(jl, 1) = 0.0
    pvph(jl, 1) = 0.0
    pulow(jl) = 0.0
    pvlow(jl) = 0.0
    zulow(jl) = 0.0
    zvlow(jl) = 0.0
    kkcrith(jl) = klev
    kkenvh(jl) = klev
    kentp(jl) = klev
    kcrit(jl) = 1
    ncount(jl) = 0
    ll1(jl, klev+1) = .FALSE.
  END DO

  ! *     define low-level flow
  ! ---------------------

  DO jk = klev, 2, -1
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        zdp(jl, jk) = papm1(jl, jk) - papm1(jl, jk-1)
        prho(jl, jk) = 2.*paphm1(jl, jk)*zcons1/(ptm1(jl,jk)+ptm1(jl,jk-1))
        pstab(jl, jk) = 2.*zcons2/(ptm1(jl,jk)+ptm1(jl,jk-1))* &
          (1.-rcpd*prho(jl,jk)*(ptm1(jl,jk)-ptm1(jl,jk-1))/zdp(jl,jk))
        pstab(jl, jk) = max(pstab(jl,jk), gssec)
      END IF
    END DO
  END DO

  ! ********************************************************************

  ! *     define blocked flow
  ! -------------------
  DO jk = klev, ilevh, -1
    DO jl = kidia, kfdia
      IF (jk>=kknub(jl) .AND. jk<=kknul(jl)) THEN
        pulow(jl) = pulow(jl) + pum1(jl, jk)*(paphm1(jl,jk+1)-paphm1(jl,jk))
        pvlow(jl) = pvlow(jl) + pvm1(jl, jk)*(paphm1(jl,jk+1)-paphm1(jl,jk))
      END IF
    END DO
  END DO
  DO jl = kidia, kfdia
    pulow(jl) = pulow(jl)/(paphm1(jl,kknul(jl)+1)-paphm1(jl,kknub(jl)))
    pvlow(jl) = pvlow(jl)/(paphm1(jl,kknul(jl)+1)-paphm1(jl,kknub(jl)))
    znorm(jl) = max(sqrt(pulow(jl)**2+pvlow(jl)**2), gvsec)
    pvph(jl, klev+1) = znorm(jl)
  END DO

  ! *******  setup orography axes and define plane of profiles  *******

  DO jl = kidia, kfdia
    lo = (pulow(jl)<gvsec) .AND. (pulow(jl)>=-gvsec)
    IF (lo) THEN
      zu = pulow(jl) + 2.*gvsec
    ELSE
      zu = pulow(jl)
    END IF
    zphi = atan(pvlow(jl)/zu)
    ppsi(jl, klev+1) = ptheta(jl)*rpi/180. - zphi
    zb(jl) = 1. - 0.18*pgamma(jl) - 0.04*pgamma(jl)**2
    zc(jl) = 0.48*pgamma(jl) + 0.3*pgamma(jl)**2
    pd1(jl) = zb(jl) - (zb(jl)-zc(jl))*(sin(ppsi(jl,klev+1))**2)
    pd2(jl) = (zb(jl)-zc(jl))*sin(ppsi(jl,klev+1))*cos(ppsi(jl,klev+1))
    pdmod(jl) = sqrt(pd1(jl)**2+pd2(jl)**2)
  END DO

  ! ************ define flow in plane of lowlevel stress *************

  DO jk = 1, klev
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        zvt1 = pulow(jl)*pum1(jl, jk) + pvlow(jl)*pvm1(jl, jk)
        zvt2 = -pvlow(jl)*pum1(jl, jk) + pulow(jl)*pvm1(jl, jk)
        zvpf(jl, jk) = (zvt1*pd1(jl)+zvt2*pd2(jl))/(znorm(jl)*pdmod(jl))
      END IF
      ptau(jl, jk) = 0.0
      pzdep(jl, jk) = 0.0
      ppsi(jl, jk) = 0.0
      ll1(jl, jk) = .FALSE.
    END DO
  END DO
  DO jk = 2, klev
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        zdp(jl, jk) = papm1(jl, jk) - papm1(jl, jk-1)
        pvph(jl, jk) = ((paphm1(jl,jk)-papm1(jl,jk-1))*zvpf(jl,jk)+(papm1(jl, &
          jk)-paphm1(jl,jk))*zvpf(jl,jk-1))/zdp(jl, jk)
        IF (pvph(jl,jk)<gvsec) THEN
          pvph(jl, jk) = gvsec
          kcrit(jl) = jk
        END IF
      END IF
    END DO
  END DO

  ! *         2.2     brunt-vaisala frequency and density at half levels.


  DO jk = ilevh, klev
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        IF (jk>=(kknub(jl)+1) .AND. jk<=kknul(jl)) THEN
          zst = zcons2/ptm1(jl, jk)*(1.-rcpd*prho(jl,jk)*(ptm1(jl, &
            jk)-ptm1(jl,jk-1))/zdp(jl,jk))
          pstab(jl, klev+1) = pstab(jl, klev+1) + zst*zdp(jl, jk)
          pstab(jl, klev+1) = max(pstab(jl,klev+1), gssec)
          prho(jl, klev+1) = prho(jl, klev+1) + paphm1(jl, jk)*2.*zdp(jl, jk) &
            *zcons1/(ptm1(jl,jk)+ptm1(jl,jk-1))
        END IF
      END IF
    END DO
  END DO

  DO jl = kidia, kfdia
    pstab(jl, klev+1) = pstab(jl, klev+1)/(papm1(jl,kknul(jl))-papm1(jl,kknub &
      (jl)))
    prho(jl, klev+1) = prho(jl, klev+1)/(papm1(jl,kknul(jl))-papm1(jl,kknub( &
      jl)))
    zvar = pstd(jl)
  END DO

  ! *         2.3     mean flow richardson number.
  ! *                 and critical height for froude layer


  DO jk = 2, klev
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        zdwind = max(abs(zvpf(jl,jk)-zvpf(jl,jk-1)), gvsec)
        pri(jl, jk) = pstab(jl, jk)*(zdp(jl,jk)/(rg*prho(jl,jk)*zdwind))**2
        pri(jl, jk) = max(pri(jl,jk), grcrit)
      END IF
    END DO
  END DO



  ! *      define top of 'envelope' layer
  ! ----------------------------

  DO jl = kidia, kfdia
    pnu(jl) = 0.0
    znum(jl) = 0.0
  END DO

  DO jk = 2, klev - 1
    DO jl = kidia, kfdia

      IF (ktest(jl)==1) THEN

        IF (jk>=kknub(jl)) THEN

          znum(jl) = pnu(jl)
          zwind = (pulow(jl)*pum1(jl,jk)+pvlow(jl)*pvm1(jl,jk))/ &
            max(sqrt(pulow(jl)**2+pvlow(jl)**2), gvsec)
          zwind = max(sqrt(zwind**2), gvsec)
          zdelp = paphm1(jl, jk+1) - paphm1(jl, jk)
          zstabm = sqrt(max(pstab(jl,jk),gssec))
          zstabp = sqrt(max(pstab(jl,jk+1),gssec))
          zrhom = prho(jl, jk)
          zrhop = prho(jl, jk+1)
          pnu(jl) = pnu(jl) + (zdelp/rg)*((zstabp/zrhop+zstabm/zrhom)/2.)/ &
            zwind
          IF ((znum(jl)<=gfrcrit) .AND. (pnu(jl)>gfrcrit) .AND. (kkenvh( &
            jl)==klev)) kkenvh(jl) = jk

        END IF

      END IF

    END DO
  END DO

  ! calculation of a dynamical mixing height for the breaking
  ! of gravity waves:


  DO jl = kidia, kfdia
    znup(jl) = 0.0
    znum(jl) = 0.0
  END DO

  DO jk = klev - 1, 2, -1
    DO jl = kidia, kfdia

      IF (ktest(jl)==1) THEN

        znum(jl) = znup(jl)
        zwind = (pulow(jl)*pum1(jl,jk)+pvlow(jl)*pvm1(jl,jk))/ &
          max(sqrt(pulow(jl)**2+pvlow(jl)**2), gvsec)
        zwind = max(sqrt(zwind**2), gvsec)
        zdelp = paphm1(jl, jk+1) - paphm1(jl, jk)
        zstabm = sqrt(max(pstab(jl,jk),gssec))
        zstabp = sqrt(max(pstab(jl,jk+1),gssec))
        zrhom = prho(jl, jk)
        zrhop = prho(jl, jk+1)
        znup(jl) = znup(jl) + (zdelp/rg)*((zstabp/zrhop+zstabm/zrhom)/2.)/ &
          zwind
        IF ((znum(jl)<=rpi/2.) .AND. (znup(jl)>rpi/2.) .AND. (kkcrith( &
          jl)==klev)) kkcrith(jl) = jk

      END IF

    END DO
  END DO

  DO jl = kidia, kfdia
    kkcrith(jl) = min0(kkcrith(jl), kknu2(jl))
    kkcrith(jl) = max0(kkcrith(jl), ilevh*2)
  END DO

  ! directional info for flow blocking *************************

  DO jk = ilevh, klev
    DO jl = kidia, kfdia
      IF (jk>=kkenvh(jl)) THEN
        lo = (pum1(jl,jk)<gvsec) .AND. (pum1(jl,jk)>=-gvsec)
        IF (lo) THEN
          zu = pum1(jl, jk) + 2.*gvsec
        ELSE
          zu = pum1(jl, jk)
        END IF
        zphi = atan(pvm1(jl,jk)/zu)
        ppsi(jl, jk) = ptheta(jl)*rpi/180. - zphi
      END IF
    END DO
  END DO
  ! forms the vertical 'leakiness' **************************

  alpha = 3.

  DO jk = ilevh, klev
    DO jl = kidia, kfdia
      IF (jk>=kkenvh(jl)) THEN
        zggeenv = amax1(1., (pgeom1(jl,kkenvh(jl))+pgeom1(jl, &
          kkenvh(jl)-1))/2.)
        zggeom1 = amax1(pgeom1(jl,jk), 1.)
        zgvar = amax1(pstd(jl)*rg, 1.)
        ! mod    pzdep(jl,jk)=sqrt((zggeenv-zggeom1)/(zggeom1+zgvar))
        pzdep(jl, jk) = (pgeom1(jl,kkenvh(jl)-1)-pgeom1(jl,jk))/ &
          (pgeom1(jl,kkenvh(jl)-1)-pgeom1(jl,klev))
      END IF
    END DO
  END DO

  RETURN
END SUBROUTINE orosetup
SUBROUTINE gwstress(nlon, nlev, ktest, kcrit, kkenvh, kknu, prho, pstab, &
    pvph, pstd, psig, pmea, ppic, ptau, pgeom1, pdmod)

  ! **** *gwstress*

  ! purpose.
  ! --------

  ! **   interface.
  ! ----------
  ! call *gwstress*  from *gwdrag*

  ! explicit arguments :
  ! --------------------
  ! ==== inputs ===
  ! ==== outputs ===

  ! implicit arguments :   none
  ! --------------------

  ! method.
  ! -------


  ! externals.
  ! ----------


  ! reference.
  ! ----------

  ! see ecmwf research department documentation of the "i.f.s."

  ! author.
  ! -------

  ! modifications.
  ! --------------
  ! f. lott put the new gwd on ifs      22/11/93

  ! -----------------------------------------------------------------------
USE yoegwd_mod_h
    USE dimphy
  USE yomcst_mod_h
IMPLICIT NONE


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

  ! *       0.1   arguments
  ! ---------

  INTEGER nlon, nlev
  INTEGER kcrit(nlon), ktest(nlon), kkenvh(nlon), kknu(nlon)

  REAL prho(nlon, nlev+1), pstab(nlon, nlev+1), ptau(nlon, nlev+1), &
    pvph(nlon, nlev+1), pgeom1(nlon, nlev), pstd(nlon)

  REAL psig(nlon)
  REAL pmea(nlon), ppic(nlon)
  REAL pdmod(nlon)

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

  ! *       0.2   local arrays
  ! ------------
  INTEGER jl
  REAL zblock, zvar, zeff
  LOGICAL lo

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

  ! *       0.3   functions
  ! ---------
  ! ------------------------------------------------------------------

  ! *         1.    initialization
  ! --------------


  ! *         3.1     gravity wave stress.



  DO jl = kidia, kfdia
    IF (ktest(jl)==1) THEN

      ! effective mountain height above the blocked flow

      IF (kkenvh(jl)==klev) THEN
        zblock = 0.0
      ELSE
        zblock = (pgeom1(jl,kkenvh(jl))+pgeom1(jl,kkenvh(jl)+1))/2./rg
      END IF

      zvar = ppic(jl) - pmea(jl)
      zeff = amax1(0., zvar-zblock)

      ptau(jl, klev+1) = prho(jl, klev+1)*gkdrag*psig(jl)*zeff**2/4./ &
        pstd(jl)*pvph(jl, klev+1)*pdmod(jl)*sqrt(pstab(jl,klev+1))

      ! too small value of stress or  low level flow include critical level
      ! or low level flow:  gravity wave stress nul.

      lo = (ptau(jl,klev+1)<gtsec) .OR. (kcrit(jl)>=kknu(jl)) .OR. &
        (pvph(jl,klev+1)<gvcrit)
      ! if(lo) ptau(jl,klev+1)=0.0

    ELSE

      ptau(jl, klev+1) = 0.0

    END IF

  END DO

  RETURN
END SUBROUTINE gwstress
SUBROUTINE gwprofil(nlon, nlev, kgwd, kdx, ktest, kkcrith, kcrit, paphm1, &
    prho, pstab, pvph, pri, ptau, pdmod, psig, pvar)

  ! **** *GWPROFIL*

  ! PURPOSE.
  ! --------

  ! **   INTERFACE.
  ! ----------
  ! FROM *GWDRAG*

  ! EXPLICIT ARGUMENTS :
  ! --------------------
  ! ==== INPUTS ===
  ! ==== OUTPUTS ===

  ! IMPLICIT ARGUMENTS :   NONE
  ! --------------------

  ! METHOD:
  ! -------
  ! THE STRESS PROFILE FOR GRAVITY WAVES IS COMPUTED AS FOLLOWS:
  ! IT IS CONSTANT (NO GWD) AT THE LEVELS BETWEEN THE GROUND
  ! AND THE TOP OF THE BLOCKED LAYER (KKENVH).
  ! IT DECREASES LINEARLY WITH HEIGHTS FROM THE TOP OF THE
  ! BLOCKED LAYER TO 3*VAROR (kKNU), TO SIMULATES LEE WAVES OR
  ! NONLINEAR GRAVITY WAVE BREAKING.
  ! ABOVE IT IS CONSTANT, EXCEPT WHEN THE WAVE ENCOUNTERS A CRITICAL
  ! LEVEL (KCRIT) OR WHEN IT BREAKS.



  ! EXTERNALS.
  ! ----------


  ! REFERENCE.
  ! ----------

  ! SEE ECMWF RESEARCH DEPARTMENT DOCUMENTATION OF THE "I.F.S."

  ! AUTHOR.
  ! -------

  ! MODIFICATIONS.
  ! --------------
  ! PASSAGE OF THE NEW GWDRAG TO I.F.S. (F. LOTT, 22/11/93)
  ! -----------------------------------------------------------------------
USE yoegwd_mod_h
    USE dimphy
  USE yomcst_mod_h
IMPLICIT NONE






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

  ! *       0.1   ARGUMENTS
  ! ---------

  INTEGER nlon, nlev
  INTEGER kkcrith(nlon), kcrit(nlon), kdx(nlon), ktest(nlon)


  REAL paphm1(nlon, nlev+1), pstab(nlon, nlev+1), prho(nlon, nlev+1), &
    pvph(nlon, nlev+1), pri(nlon, nlev+1), ptau(nlon, nlev+1)

  REAL pdmod(nlon), psig(nlon), pvar(nlon)

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

  ! *       0.2   LOCAL ARRAYS
  ! ------------

  INTEGER ilevh, ji, kgwd, jl, jk
  REAL zsqr, zalfa, zriw, zdel, zb, zalpha, zdz2n
  REAL zdelp, zdelpt
  REAL zdz2(klon, klev), znorm(klon), zoro(klon)
  REAL ztau(klon, klev+1)

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

  ! *         1.    INITIALIZATION
  ! --------------

  ! print *,' entree gwprofil'


  ! *    COMPUTATIONAL CONSTANTS.
  ! ------------- ----------

  ilevh = klev/3

  ! DO 400 ji=1,kgwd
  ! jl=kdx(ji)
  ! Modif vectorisation 02/04/2004
  DO jl = kidia, kfdia
    IF (ktest(jl)==1) THEN
      zoro(jl) = psig(jl)*pdmod(jl)/4./max(pvar(jl), 1.0)
      ztau(jl, klev+1) = ptau(jl, klev+1)
    END IF
  END DO


  DO jk = klev, 2, -1

    ! *         4.1    CONSTANT WAVE STRESS UNTIL TOP OF THE
    ! BLOCKING LAYER.

    ! DO 411 ji=1,kgwd
    ! jl=kdx(ji)
    ! Modif vectorisation 02/04/2004
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        IF (jk>kkcrith(jl)) THEN
          ptau(jl, jk) = ztau(jl, klev+1)
          ! ENDIF
          ! IF(JK.EQ.KKCRITH(JL)) THEN
        ELSE
          ptau(jl, jk) = grahilo*ztau(jl, klev+1)
        END IF
      END IF
    END DO

    ! *         4.15   CONSTANT SHEAR STRESS UNTIL THE TOP OF THE
    ! LOW LEVEL FLOW LAYER.


    ! *         4.2    WAVE DISPLACEMENT AT NEXT LEVEL.


    ! DO 421 ji=1,kgwd
    ! jl=kdx(ji)
    ! Modif vectorisation 02/04/2004
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        IF (jk<kkcrith(jl)) THEN
          znorm(jl) = gkdrag*prho(jl, jk)*sqrt(pstab(jl,jk))*pvph(jl, jk)* &
            zoro(jl)
          zdz2(jl, jk) = ptau(jl, jk+1)/max(znorm(jl), gssec)
        END IF
      END IF
    END DO

    ! *         4.3    WAVE RICHARDSON NUMBER, NEW WAVE DISPLACEMENT
    ! *                AND STRESS:  BREAKING EVALUATION AND CRITICAL
    ! LEVEL


    ! DO 431 ji=1,kgwd
    ! jl=Kdx(ji)
    ! Modif vectorisation 02/04/2004
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN

        IF (jk<kkcrith(jl)) THEN
          IF ((ptau(jl,jk+1)<gtsec) .OR. (jk<=kcrit(jl))) THEN
            ptau(jl, jk) = 0.0
          ELSE
            zsqr = sqrt(pri(jl,jk))
            zalfa = sqrt(pstab(jl,jk)*zdz2(jl,jk))/pvph(jl, jk)
            zriw = pri(jl, jk)*(1.-zalfa)/(1+zalfa*zsqr)**2
            IF (zriw<grcrit) THEN
              zdel = 4./zsqr/grcrit + 1./grcrit**2 + 4./grcrit
              zb = 1./grcrit + 2./zsqr
              zalpha = 0.5*(-zb+sqrt(zdel))
              zdz2n = (pvph(jl,jk)*zalpha)**2/pstab(jl, jk)
              ptau(jl, jk) = znorm(jl)*zdz2n
            ELSE
              ptau(jl, jk) = znorm(jl)*zdz2(jl, jk)
            END IF
            ptau(jl, jk) = min(ptau(jl,jk), ptau(jl,jk+1))
          END IF
        END IF
      END IF
    END DO

  END DO

  ! REORGANISATION OF THE STRESS PROFILE AT LOW LEVEL

  ! DO 530 ji=1,kgwd
  ! jl=kdx(ji)
  ! Modif vectorisation 02/04/2004
  DO jl = kidia, kfdia
    IF (ktest(jl)==1) THEN
      ztau(jl, kkcrith(jl)) = ptau(jl, kkcrith(jl))
      ztau(jl, nstra) = ptau(jl, nstra)
    END IF
  END DO

  DO jk = 1, klev

    ! DO 532 ji=1,kgwd
    ! jl=kdx(ji)
    ! Modif vectorisation 02/04/2004
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN


        IF (jk>kkcrith(jl)) THEN

          zdelp = paphm1(jl, jk) - paphm1(jl, klev+1)
          zdelpt = paphm1(jl, kkcrith(jl)) - paphm1(jl, klev+1)
          ptau(jl, jk) = ztau(jl, klev+1) + (ztau(jl,kkcrith(jl))-ztau(jl, &
            klev+1))*zdelp/zdelpt

        END IF

      END IF
    END DO

    ! REORGANISATION IN THE STRATOSPHERE

    ! DO 533 ji=1,kgwd
    ! jl=kdx(ji)
    ! Modif vectorisation 02/04/2004
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN


        IF (jk<nstra) THEN

          zdelp = paphm1(jl, nstra)
          zdelpt = paphm1(jl, jk)
          ptau(jl, jk) = ztau(jl, nstra)*zdelpt/zdelp

        END IF

      END IF
    END DO

    ! REORGANISATION IN THE TROPOSPHERE

    ! DO 534 ji=1,kgwd
    ! jl=kdx(ji)
    ! Modif vectorisation 02/04/2004
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN


        IF (jk<kkcrith(jl) .AND. jk>nstra) THEN

          zdelp = paphm1(jl, jk) - paphm1(jl, kkcrith(jl))
          zdelpt = paphm1(jl, nstra) - paphm1(jl, kkcrith(jl))
          ptau(jl, jk) = ztau(jl, kkcrith(jl)) + (ztau(jl,nstra)-ztau(jl, &
            kkcrith(jl)))*zdelp/zdelpt

        END IF
      END IF
    END DO


  END DO


  RETURN
END SUBROUTINE gwprofil
SUBROUTINE lift_noro(nlon, nlev, dtime, paprs, pplay, plat, pmea, pstd, ppic, &
    ktest, t, u, v, pulow, pvlow, pustr, pvstr, d_t, d_u, d_v)

  USE dimphy
  USE yomcst_mod_h
IMPLICIT NONE
  ! ======================================================================
  ! Auteur(s): F.Lott (LMD/CNRS) date: 19950201
  ! Objet: Frottement de la montagne Interface
  ! ======================================================================
  ! Arguments:
  ! dtime---input-R- pas d'integration (s)
  ! paprs---input-R-pression pour chaque inter-couche (en Pa)
  ! pplay---input-R-pression pour le mileu de chaque couche (en Pa)
  ! t-------input-R-temperature (K)
  ! u-------input-R-vitesse horizontale (m/s)
  ! v-------input-R-vitesse horizontale (m/s)

  ! d_t-----output-R-increment de la temperature
  ! d_u-----output-R-increment de la vitesse u
  ! d_v-----output-R-increment de la vitesse v
  ! ======================================================================


  ! ARGUMENTS

  INTEGER nlon, nlev
  REAL dtime
  REAL paprs(klon, klev+1)
  REAL pplay(klon, klev)
  REAL plat(nlon), pmea(nlon)
  REAL pstd(nlon)
  REAL ppic(nlon)
  REAL pulow(nlon), pvlow(nlon), pustr(nlon), pvstr(nlon)
  REAL t(nlon, nlev), u(nlon, nlev), v(nlon, nlev)
  REAL d_t(nlon, nlev), d_u(nlon, nlev), d_v(nlon, nlev)

  INTEGER i, k, ktest(nlon)

  ! Variables locales:

  REAL zgeom(klon, klev)
  REAL pdtdt(klon, klev), pdudt(klon, klev), pdvdt(klon, klev)
  REAL pt(klon, klev), pu(klon, klev), pv(klon, klev)
  REAL papmf(klon, klev), papmh(klon, klev+1)

  ! initialiser les variables de sortie (pour securite)

  DO i = 1, klon
    pulow(i) = 0.0
    pvlow(i) = 0.0
    pustr(i) = 0.0
    pvstr(i) = 0.0
  END DO
  DO k = 1, klev
    DO i = 1, klon
      d_t(i, k) = 0.0
      d_u(i, k) = 0.0
      d_v(i, k) = 0.0
      pdudt(i, k) = 0.0
      pdvdt(i, k) = 0.0
      pdtdt(i, k) = 0.0
    END DO
  END DO

  ! preparer les variables d'entree (attention: l'ordre des niveaux
  ! verticaux augmente du haut vers le bas)

  DO k = 1, klev
    DO i = 1, klon
      pt(i, k) = t(i, klev-k+1)
      pu(i, k) = u(i, klev-k+1)
      pv(i, k) = v(i, klev-k+1)
      papmf(i, k) = pplay(i, klev-k+1)
    END DO
  END DO
  DO k = 1, klev + 1
    DO i = 1, klon
      papmh(i, k) = paprs(i, klev-k+2)
    END DO
  END DO
  DO i = 1, klon
    zgeom(i, klev) = rd*pt(i, klev)*log(papmh(i,klev+1)/papmf(i,klev))
  END DO
  DO k = klev - 1, 1, -1
    DO i = 1, klon
      zgeom(i, k) = zgeom(i, k+1) + rd*(pt(i,k)+pt(i,k+1))/2.0*log(papmf(i,k+ &
        1)/papmf(i,k))
    END DO
  END DO

  ! appeler la routine principale

  CALL orolift(klon, klev, ktest, dtime, papmh, zgeom, pt, pu, pv, plat, &
    pmea, pstd, ppic, pulow, pvlow, pdudt, pdvdt, pdtdt)

  DO k = 1, klev
    DO i = 1, klon
      d_u(i, klev+1-k) = dtime*pdudt(i, k)
      d_v(i, klev+1-k) = dtime*pdvdt(i, k)
      d_t(i, klev+1-k) = dtime*pdtdt(i, k)
      pustr(i) = pustr(i) &        ! IM BUG .
                                   ! +RG*pdudt(i,k)*(papmh(i,k+1)-papmh(i,k))
        +pdudt(i, k)*(papmh(i,k+1)-papmh(i,k))/rg
      pvstr(i) = pvstr(i) &        ! IM BUG .
                                   ! +RG*pdvdt(i,k)*(papmh(i,k+1)-papmh(i,k))
        +pdvdt(i, k)*(papmh(i,k+1)-papmh(i,k))/rg
    END DO
  END DO

  RETURN
END SUBROUTINE lift_noro
SUBROUTINE orolift(nlon, nlev, ktest, ptsphy, paphm1, pgeom1, ptm1, pum1, &
    pvm1, plat, pmea, pvaror, ppic & ! OUTPUTS
    , pulow, pvlow, pvom, pvol, pte)


  ! **** *OROLIFT: SIMULATE THE GEOSTROPHIC LIFT.

  ! PURPOSE.
  ! --------

  ! **   INTERFACE.
  ! ----------
  ! CALLED FROM *lift_noro
  ! ----------

  ! AUTHOR.
  ! -------
  ! F.LOTT  LMD 22/11/95

USE yoegwd_mod_h
    USE dimphy
  USE yomcst_mod_h
IMPLICIT NONE



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

  ! *       0.1   ARGUMENTS
  ! ---------


  INTEGER nlon, nlev
  REAL pte(nlon, nlev), pvol(nlon, nlev), pvom(nlon, nlev), pulow(nlon), &
    pvlow(nlon)
  REAL pum1(nlon, nlev), pvm1(nlon, nlev), ptm1(nlon, nlev), plat(nlon), &
    pmea(nlon), pvaror(nlon), ppic(nlon), pgeom1(nlon, nlev), &
    paphm1(nlon, nlev+1)

  INTEGER ktest(nlon)
  REAL ptsphy
  ! -----------------------------------------------------------------------

  ! *       0.2   LOCAL ARRAYS
  ! ------------
  LOGICAL lifthigh
  ! ym      integer klevm1, jl, ilevh, jk
  INTEGER jl, ilevh, jk
  REAL zcons1, ztmst, zrtmst, zpi, zhgeo
  REAL zdelp, zslow, zsqua, zscav, zbet
  INTEGER iknub(klon), iknul(klon)
  LOGICAL ll1(klon, klev+1)

  REAL ztau(klon, klev+1), ztav(klon, klev+1), zrho(klon, klev+1)
  REAL zdudt(klon), zdvdt(klon)
  REAL zhcrit(klon, klev)
  CHARACTER (LEN=20) :: modname = 'orografi'
  CHARACTER (LEN=80) :: abort_message
  ! -----------------------------------------------------------------------

  ! *         1.1  INITIALIZATIONS
  ! ---------------

  lifthigh = .FALSE.

  IF (nlon/=klon .OR. nlev/=klev) THEN
    abort_message = 'pb dimension'
    CALL abort_physic(modname, abort_message, 1)
  END IF
  zcons1 = 1./rd
  ! ym      KLEVM1=KLEV-1
  ztmst = ptsphy
  zrtmst = 1./ztmst
  zpi = acos(-1.)

  DO jl = kidia, kfdia
    zrho(jl, klev+1) = 0.0
    pulow(jl) = 0.0
    pvlow(jl) = 0.0
    iknub(jl) = klev
    iknul(jl) = klev
    ilevh = klev/3
    ll1(jl, klev+1) = .FALSE.
    DO jk = 1, klev
      pvom(jl, jk) = 0.0
      pvol(jl, jk) = 0.0
      pte(jl, jk) = 0.0
    END DO
  END DO


  ! *         2.1     DEFINE LOW LEVEL WIND, PROJECT WINDS IN PLANE OF
  ! *                 LOW LEVEL WIND, DETERMINE SECTOR IN WHICH TO TAKE
  ! *                 THE VARIANCE AND SET INDICATOR FOR CRITICAL LEVELS.



  DO jk = klev, 1, -1
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        zhcrit(jl, jk) = amax1(ppic(jl)-pmea(jl), 100.)
        zhgeo = pgeom1(jl, jk)/rg
        ll1(jl, jk) = (zhgeo>zhcrit(jl,jk))
        IF (ll1(jl,jk) .NEQV. ll1(jl,jk+1)) THEN
          iknub(jl) = jk
        END IF
      END IF
    END DO
  END DO

  DO jl = kidia, kfdia
    IF (ktest(jl)==1) THEN
      iknub(jl) = max(iknub(jl), klev/2)
      iknul(jl) = max(iknul(jl), 2*klev/3)
      IF (iknub(jl)>nktopg) iknub(jl) = nktopg
      IF (iknub(jl)==nktopg) iknul(jl) = klev
      IF (iknub(jl)==iknul(jl)) iknub(jl) = iknul(jl) - 1
    END IF
  END DO

  ! do 2011 jl=kidia,kfdia
  ! IF(KTEST(JL).EQ.1) THEN
  ! print *,' iknul= ',iknul(jl),'  iknub=',iknub(jl)
  ! ENDIF
  ! 2011 continue

  ! PRINT *,'  DANS OROLIFT: 2010'

  DO jk = klev, 2, -1
    DO jl = kidia, kfdia
      zrho(jl, jk) = 2.*paphm1(jl, jk)*zcons1/(ptm1(jl,jk)+ptm1(jl,jk-1))
    END DO
  END DO
  ! PRINT *,'  DANS OROLIFT: 223'

  ! ********************************************************************

  ! *     DEFINE LOW LEVEL FLOW
  ! -------------------
  DO jk = klev, 1, -1
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        IF (jk>=iknub(jl) .AND. jk<=iknul(jl)) THEN
          pulow(jl) = pulow(jl) + pum1(jl, jk)*(paphm1(jl,jk+1)-paphm1(jl,jk) &
            )
          pvlow(jl) = pvlow(jl) + pvm1(jl, jk)*(paphm1(jl,jk+1)-paphm1(jl,jk) &
            )
          zrho(jl, klev+1) = zrho(jl, klev+1) + zrho(jl, jk)*(paphm1(jl,jk+1) &
            -paphm1(jl,jk))
        END IF
      END IF
    END DO
  END DO
  DO jl = kidia, kfdia
    IF (ktest(jl)==1) THEN
      pulow(jl) = pulow(jl)/(paphm1(jl,iknul(jl)+1)-paphm1(jl,iknub(jl)))
      pvlow(jl) = pvlow(jl)/(paphm1(jl,iknul(jl)+1)-paphm1(jl,iknub(jl)))
      zrho(jl, klev+1) = zrho(jl, klev+1)/(paphm1(jl,iknul(jl)+1)-paphm1(jl, &
        iknub(jl)))
    END IF
  END DO

  ! ***********************************************************

  ! *         3.      COMPUTE MOUNTAIN LIFT


  DO jl = kidia, kfdia
    IF (ktest(jl)==1) THEN
      ztau(jl, klev+1) = -gklift*zrho(jl, klev+1)*2.*romega* & ! *
                                                               ! (2*PVAROR(JL)+PMEA(JL))*
        2*pvaror(jl)*sin(zpi/180.*plat(jl))*pvlow(jl)
      ztav(jl, klev+1) = gklift*zrho(jl, klev+1)*2.*romega* & ! *
                                                              ! (2*PVAROR(JL)+PMEA(JL))*
        2*pvaror(jl)*sin(zpi/180.*plat(jl))*pulow(jl)
    ELSE
      ztau(jl, klev+1) = 0.0
      ztav(jl, klev+1) = 0.0
    END IF
  END DO

  ! *         4.      COMPUTE LIFT PROFILE
  ! *                 --------------------



  DO jk = 1, klev
    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        ztau(jl, jk) = ztau(jl, klev+1)*paphm1(jl, jk)/paphm1(jl, klev+1)
        ztav(jl, jk) = ztav(jl, klev+1)*paphm1(jl, jk)/paphm1(jl, klev+1)
      ELSE
        ztau(jl, jk) = 0.0
        ztav(jl, jk) = 0.0
      END IF
    END DO
  END DO


  ! *         5.      COMPUTE TENDENCIES.
  ! *                 -------------------
  IF (lifthigh) THEN
    ! PRINT *,'  DANS OROLIFT: 500'

    ! EXPLICIT SOLUTION AT ALL LEVELS

    DO jk = 1, klev
      DO jl = kidia, kfdia
        IF (ktest(jl)==1) THEN
          zdelp = paphm1(jl, jk+1) - paphm1(jl, jk)
          zdudt(jl) = -rg*(ztau(jl,jk+1)-ztau(jl,jk))/zdelp
          zdvdt(jl) = -rg*(ztav(jl,jk+1)-ztav(jl,jk))/zdelp
        END IF
      END DO
    END DO

    ! PROJECT PERPENDICULARLY TO U NOT TO DESTROY ENERGY

    DO jk = 1, klev
      DO jl = kidia, kfdia
        IF (ktest(jl)==1) THEN

          zslow = sqrt(pulow(jl)**2+pvlow(jl)**2)
          zsqua = amax1(sqrt(pum1(jl,jk)**2+pvm1(jl,jk)**2), gvsec)
          zscav = -zdudt(jl)*pvm1(jl, jk) + zdvdt(jl)*pum1(jl, jk)
          IF (zsqua>gvsec) THEN
            pvom(jl, jk) = -zscav*pvm1(jl, jk)/zsqua**2
            pvol(jl, jk) = zscav*pum1(jl, jk)/zsqua**2
          ELSE
            pvom(jl, jk) = 0.0
            pvol(jl, jk) = 0.0
          END IF
          zsqua = sqrt(pum1(jl,jk)**2+pum1(jl,jk)**2)
          IF (zsqua<zslow) THEN
            pvom(jl, jk) = zsqua/zslow*pvom(jl, jk)
            pvol(jl, jk) = zsqua/zslow*pvol(jl, jk)
          END IF

        END IF
      END DO
    END DO

    ! 6.  LOW LEVEL LIFT, SEMI IMPLICIT:
    ! ----------------------------------

  ELSE

    DO jl = kidia, kfdia
      IF (ktest(jl)==1) THEN
        DO jk = klev, iknub(jl), -1
          zbet = gklift*2.*romega*sin(zpi/180.*plat(jl))*ztmst* &
            (pgeom1(jl,iknub(jl)-1)-pgeom1(jl,jk))/ &
            (pgeom1(jl,iknub(jl)-1)-pgeom1(jl,klev))
          zdudt(jl) = -pum1(jl, jk)/ztmst/(1+zbet**2)
          zdvdt(jl) = -pvm1(jl, jk)/ztmst/(1+zbet**2)
          pvom(jl, jk) = zbet**2*zdudt(jl) - zbet*zdvdt(jl)
          pvol(jl, jk) = zbet*zdudt(jl) + zbet**2*zdvdt(jl)
        END DO
      END IF
    END DO

  END IF

  RETURN
END SUBROUTINE orolift


SUBROUTINE sugwd(nlon, nlev, paprs, pplay)
USE yoegwd_mod_h
    USE dimphy
  USE mod_phys_lmdz_para
  USE mod_grid_phy_lmdz
  ! USE parallel

  ! **** *SUGWD* INITIALIZE COMMON YOEGWD CONTROLLING GRAVITY WAVE DRAG

  ! PURPOSE.
  ! --------
  ! INITIALIZE YOEGWD, THE COMMON THAT CONTROLS THE
  ! GRAVITY WAVE DRAG PARAMETRIZATION.

  ! **   INTERFACE.
  ! ----------
  ! CALL *SUGWD* FROM *SUPHEC*
  ! -----        ------

  ! EXPLICIT ARGUMENTS :
  ! --------------------
  ! PSIG        : VERTICAL COORDINATE TABLE
  ! NLEV        : NUMBER OF MODEL LEVELS

  ! IMPLICIT ARGUMENTS :
  ! --------------------
  ! COMMON YOEGWD

  ! METHOD.
  ! -------
  ! SEE DOCUMENTATION

  ! EXTERNALS.
  ! ----------
  ! NONE

  ! REFERENCE.
  ! ----------
  ! ECMWF Research Department documentation of the IFS

  ! AUTHOR.
  ! -------
  ! MARTIN MILLER             *ECMWF*

  ! MODIFICATIONS.
  ! --------------
  ! ORIGINAL : 90-01-01
  ! ------------------------------------------------------------------
  IMPLICIT NONE

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

  INTEGER nlon, nlev, jk
  REAL paprs(nlon, nlev+1)
  REAL pplay(nlon, nlev)
  REAL zpr, zstra, zsigt, zpm1r
  REAL :: pplay_glo(klon_glo, nlev)
  REAL :: paprs_glo(klon_glo, nlev+1)

  ! *       1.    SET THE VALUES OF THE PARAMETERS
  ! --------------------------------


  PRINT *, ' DANS SUGWD NLEV=', nlev
  ghmax = 10000.

  zpr = 100000.
  zstra = 0.1
  zsigt = 0.94
  ! old  ZPR=80000.
  ! old  ZSIGT=0.85


  CALL gather(pplay, pplay_glo)
  CALL bcast(pplay_glo)
  CALL gather(paprs, paprs_glo)
  CALL bcast(paprs_glo)


  DO jk = 1, nlev
    zpm1r = pplay_glo((klon_glo/2)+1, jk)/paprs_glo((klon_glo/2)+1, 1)
    IF (zpm1r>=zsigt) THEN
      nktopg = jk
    END IF
    zpm1r = pplay_glo((klon_glo/2)+1, jk)/paprs_glo((klon_glo/2)+1, 1)
    IF (zpm1r>=zstra) THEN
      nstra = jk
    END IF
  END DO



  ! inversion car dans orodrag on compte les niveaux a l'envers
  nktopg = nlev - nktopg + 1
  nstra = nlev - nstra
  PRINT *, ' DANS SUGWD nktopg=', nktopg
  PRINT *, ' DANS SUGWD nstra=', nstra

  gsigcr = 0.80

!  Values now specified in run.def, or conf_phys_m.F90
!  gkdrag = 0.2
!  grahilo = 1.
!  grcrit = 0.01
!  gfrcrit = 1.0
!  gkwake = 0.50
! gklift = 0.50
  gvcrit = 0.0

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

  ! *       2.    SET VALUES OF SECURITY PARAMETERS
  ! ---------------------------------


  gvsec = 0.10
  gssec = 1.E-12

  gtsec = 1.E-07

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

  RETURN
END SUBROUTINE sugwd