source: LMDZ6/branches/Amaury_dev/libf/dynphy_lonlat/phylmd/etat0dyn_netcdf.F90 @ 5139

MODULE etat0dyn

  !*******************************************************************************
  ! Purpose: Create dynamical initial state using atmospheric fields from a
  !          database of atmospheric to initialize the model.
  !-------------------------------------------------------------------------------
  ! Comments:

  !    *  This module is designed to work for Earth (and with ioipsl)

  !    *  etat0dyn_netcdf routine can access to NetCDF data through the following
  !  routine (to be called after restget):
  !    CALL startget_dyn3d(varname, lon_in,  lat_in, pls, workvar,&
  !                          champ, lon_in2, lat_in2)

  !    *  Variables should have the following names in the NetCDF files:
  !            'U'      : East ward wind              (in "ECDYN.nc")
  !            'V'      : Northward wind              (in "ECDYN.nc")
  !            'TEMP'   : Temperature                 (in "ECDYN.nc")
  !            'R'      : Relative humidity           (in "ECDYN.nc")
  !            'RELIEF' : High resolution orography   (in "Relief.nc")

  !    * The land mask and corresponding weights can be:
  !      1) already known (in particular if etat0dyn has been called before) ;
  !         in this case, ANY(masque(:,:)/=-99999.) = .TRUE.
  !      2) computed using the ocean mask from the ocean model (to ensure ocean
  !         fractions are the same for atmosphere and ocean) for coupled runs.
  !         File name: "o2a.nc"  ;  variable name: "OceMask"
  !      3) computed from topography file "Relief.nc" for forced runs.

  !   *   There is a big mess with the longitude size. Should it be iml or iml+1 ?
  !  I have chosen to use the iml+1 as an argument to this routine and we declare
  !  internaly smaller fields when needed. This needs to be cleared once and for
  !  all in LMDZ. A convention is required.
  !-------------------------------------------------------------------------------
  USE ioipsl, ONLY: flininfo, flinopen, flinget, flinclo, histclo
  USE lmdz_assert_eq, ONLY: assert_eq
  USE comconst_mod, ONLY: pi, cpp, kappa
  USE comvert_mod, ONLY: ap, bp, preff, pressure_exner
  USE temps_mod, ONLY: annee_ref, day_ref, itau_dyn, itau_phy, start_time
  USE lmdz_strings, ONLY: strLower
  USE lmdz_iniprint, ONLY: lunout, prt_level
  USE lmdz_comdissnew, ONLY: lstardis, nitergdiv, nitergrot, niterh, tetagdiv, &
          tetagrot, tetatemp, coefdis, vert_prof_dissip
  USE lmdz_comgeom2

  IMPLICIT NONE

  PRIVATE
  PUBLIC :: etat0dyn_netcdf

  INCLUDE "dimensions.h"
  INCLUDE "paramet.h"
  REAL, SAVE :: deg2rad
  INTEGER, SAVE :: iml_dyn, jml_dyn, llm_dyn, ttm_dyn, fid_dyn
  REAL, ALLOCATABLE, SAVE :: lon_dyn(:, :), lat_dyn(:, :), levdyn_ini(:)
  CHARACTER(LEN = 120), PARAMETER :: dynfname = 'ECDYN.nc'

CONTAINS

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

  SUBROUTINE etat0dyn_netcdf(masque, phis)

    !-------------------------------------------------------------------------------
    ! Purpose: Create dynamical initial states.
    !-------------------------------------------------------------------------------
    ! Notes:  1) This routine is designed to work for Earth
    !         2) If masque(:,:)/=-99999., masque and phis are already known.
    !         Otherwise: compute it.
    !-------------------------------------------------------------------------------
    USE control_mod
    USE regr_lat_time_coefoz_m, ONLY: regr_lat_time_coefoz
    USE regr_pr_o3_m, ONLY: regr_pr_o3
    USE press_coefoz_m, ONLY: press_coefoz
    USE exner_hyb_m, ONLY: exner_hyb
    USE exner_milieu_m, ONLY: exner_milieu
    USE infotrac, ONLY: nqtot, tracers
    USE lmdz_filtreg
    USE lmdz_cppkeys_wrapper, ONLY: CPPKEY_INCA
    USE lmdz_q_sat, ONLY: q_sat
    IMPLICIT NONE
    !-------------------------------------------------------------------------------
    ! Arguments:
    REAL, INTENT(INOUT) :: masque(iip1, jjp1)   !--- Land-ocean mask
    REAL, INTENT(INOUT) :: phis  (iip1, jjp1)   !--- Ground geopotential
    !-------------------------------------------------------------------------------
    ! Local variables:
    CHARACTER(LEN = 256) :: modname, fmt
    INTEGER :: i, j, l, ji, itau, iday, iq
    REAL :: xpn, xps, time, phystep
    REAL, DIMENSION(iip1, jjp1) :: psol
    REAL, DIMENSION(iip1, jjp1, llm + 1) :: p3d
    REAL, DIMENSION(iip1, jjp1, llm) :: uvent, t3d, tpot, qsat, qd
    REAL, DIMENSION(iip1, jjp1, llm) :: pk, pls, y, masse
    REAL, DIMENSION(iip1, jjm, llm) :: vvent
    REAL, DIMENSION(ip1jm, llm) :: pbarv
    REAL, DIMENSION(ip1jmp1, llm) :: pbaru, phi, w
    REAL, DIMENSION(ip1jmp1) :: pks
    REAL, DIMENSION(iim) :: xppn, xpps
    REAL, ALLOCATABLE :: q3d(:, :, :, :)
    !-------------------------------------------------------------------------------
    modname = 'etat0dyn_netcdf'

    deg2rad = pi / 180.0
    y(:, :, :) = 0  !ym warning unitialized variable

    ! Compute psol AND tsol, knowing phis.
    !*******************************************************************************
    CALL start_init_dyn(rlonv, rlatu, rlonu, rlatv, phis, psol)

    ! Mid-levels pressure computation
    !*******************************************************************************
    CALL pression(ip1jmp1, ap, bp, psol, p3d)             !--- Update p3d
    IF(pressure_exner) THEN                               !--- Update pk, pks
      CALL exner_hyb   (ip1jmp1, psol, p3d, pks, pk)
    ELSE
      CALL exner_milieu(ip1jmp1, psol, p3d, pks, pk)
    END IF
    pls(:, :, :) = preff * (pk(:, :, :) / cpp)**(1. / kappa)          !--- Update pls

    ! Update uvent, vvent, t3d and tpot
    !*******************************************************************************
    uvent(:, :, :) = 0.0 ; vvent(:, :, :) = 0.0 ; t3d (:, :, :) = 0.0
    CALL startget_dyn3d('u', rlonu, rlatu, pls, y, uvent, rlonv, rlatv)
    CALL startget_dyn3d('v', rlonv, rlatv, pls(:, :jjm, :), y(:, :jjm, :), vvent, &
            rlonu, rlatu(:jjm))
    CALL startget_dyn3d('t', rlonv, rlatu, pls, y, t3d, rlonu, rlatv)
    tpot(:, :, :) = t3d(:, :, :)
    CALL startget_dyn3d('tpot', rlonv, rlatu, pls, pk, tpot, rlonu, rlatv)

    WRITE(lunout, *) 'T3D min,max:', MINVAL(t3d(:, :, :)), MAXVAL(t3d(:, :, :))
    WRITE(lunout, *) 'PLS min,max:', MINVAL(pls(:, :, :)), MAXVAL(pls(:, :, :))

    ! Humidity at saturation computation
    !*******************************************************************************
    WRITE(lunout, *) 'avant q_sat'
    CALL q_sat(llm * jjp1 * iip1, t3d, pls, qsat)
    WRITE(lunout, *) 'apres q_sat'
    WRITE(lunout, *) 'QSAT min,max:', MINVAL(qsat(:, :, :)), MAXVAL(qsat(:, :, :))
    !  WRITE(lunout,*) 'QSAT :',qsat(10,20,:)
    qd (:, :, :) = 0.0
    CALL startget_dyn3d('q', rlonv, rlatu, pls, qsat, qd, rlonu, rlatv)
    ALLOCATE(q3d(iip1, jjp1, llm, nqtot)); q3d(:, :, :, :) = 0.0 ; q3d(:, :, :, 1) = qd(:, :, :)
    CALL flinclo(fid_dyn)

    ! Parameterization of ozone chemistry:
    !*******************************************************************************
    ! Look for ozone tracer:
    IF (CPPKEY_INCA) THEN
      DO iq = 1, nqtot; IF(strLower(tracers(iq)%name)=="o3") EXIT;
      END DO
      IF(iq/=nqtot + 1) THEN
        CALL regr_lat_time_coefoz
        CALL press_coefoz
        CALL regr_pr_o3(p3d, q3d(:, :, :, iq))
        q3d(:, :, :, iq) = q3d(:, :, :, iq) * 48. / 29.                !--- Mole->mass fraction
      END IF
    END IF
    q3d(iip1, :, :, :) = q3d(1, :, :, :)

    ! Writing
    !*******************************************************************************
    CALL inidissip(lstardis, nitergdiv, nitergrot, niterh, tetagdiv, tetagrot, &
            tetatemp, vert_prof_dissip)
    WRITE(lunout, *)'sortie inidissip'
    itau = 0
    itau_dyn = 0
    itau_phy = 0
    iday = dayref + itau / day_step
    time = FLOAT(itau - (iday - dayref) * day_step) / day_step
    IF(time>1.) THEN
      time = time - 1
      iday = iday + 1
    END IF
    day_ref = dayref
    annee_ref = anneeref
    CALL geopot(ip1jmp1, tpot, pk, pks, phis, phi)
    WRITE(lunout, *)'sortie geopot'
    CALL caldyn0(itau, uvent, vvent, tpot, psol, masse, pk, phis, &
            phi, w, pbaru, pbarv, time + iday - dayref)
    WRITE(lunout, *)'sortie caldyn0'
    start_time = 0.
#ifdef CPP_PARA
  CALL dynredem0_loc( "start.nc", dayref, phis)
#else
    CALL dynredem0("start.nc", dayref, phis)
#endif
    WRITE(lunout, *)'sortie dynredem0'
#ifdef CPP_PARA
  CALL dynredem1_loc( "start.nc", 0.0, vvent, uvent, tpot, q3d, masse, psol)
#else
    CALL dynredem1("start.nc", 0.0, vvent, uvent, tpot, q3d, masse, psol)
#endif
    WRITE(lunout, *)'sortie dynredem1'
    CALL histclo()

  END SUBROUTINE etat0dyn_netcdf

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


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

  SUBROUTINE startget_dyn3d(var, lon_in, lat_in, pls, workvar, &
          champ, lon_in2, lat_in2)


    IMPLICIT NONE
    !===============================================================================
    ! Purpose: Compute some quantities (u,v,t,q,tpot) using variables U,V,TEMP and R
    !     (3D fields) of file dynfname.
    !-------------------------------------------------------------------------------
    ! Note: An input auxilliary field "workvar" has to be specified in two cases:
    !     * for "q":    the saturated humidity.
    !     * for "tpot": the Exner function.
    !===============================================================================
    ! Arguments:
    CHARACTER(LEN = *), INTENT(IN) :: var
    REAL, INTENT(IN) :: lon_in(:)        ! dim (iml)
    REAL, INTENT(IN) :: lat_in(:)        ! dim (jml)
    REAL, INTENT(IN) :: pls    (:, :, :) ! dim (iml, jml, lml)
    REAL, INTENT(IN) :: workvar(:, :, :) ! dim (iml, jml, lml)
    REAL, INTENT(INOUT) :: champ  (:, :, :) ! dim (iml, jml, lml)
    REAL, INTENT(IN) :: lon_in2(:)       ! dim (iml)
    REAL, INTENT(IN) :: lat_in2(:)       ! dim (jml2)
    !-------------------------------------------------------------------------------
    ! Local variables:
    CHARACTER(LEN = 10) :: vname
    CHARACTER(LEN = 256) :: msg, modname = "startget_dyn3d"
    INTEGER :: iml, jml, jml2, lml, il
    REAL :: xppn, xpps
    !-------------------------------------------------------------------------------
    iml = assert_eq([SIZE(lon_in), SIZE(pls, 1), SIZE(workvar, 1), SIZE(champ, 1), &
            SIZE(lon_in2)], TRIM(modname) // " iml")
    jml = assert_eq(SIZE(lat_in), SIZE(pls, 2), SIZE(workvar, 2), SIZE(champ, 2), &
            TRIM(modname) // " jml")
    lml = assert_eq(SIZE(pls, 3), SIZE(workvar, 3), SIZE(champ, 3), &
            TRIM(modname) // " lml")
    jml2 = SIZE(lat_in2)

    !--- CHECK IF THE FIELD IS KNOWN
    SELECT CASE(var)
    CASE('u');    vname = 'U'
    CASE('v');    vname = 'V'
    CASE('t');    vname = 'TEMP'
    CASE('q');    vname = 'R';    msg = 'humidity as the saturated humidity'
    CASE('tpot'); msg = 'potential temperature as the Exner function'
    CASE DEFAULT; msg = 'No rule to extract variable ' // TRIM(var)
    CALL abort_gcm(modname, TRIM(msg) // ' from any data set', 1)
    END SELECT

    !--- CHECK IF SOMETHING IS MISSING
    IF((var=='tpot'.OR.var=='q').AND.MINVAL(workvar)==MAXVAL(workvar)) THEN
      msg = 'Could not compute ' // TRIM(msg) // ' is missing or constant.'
      CALL abort_gcm(modname, TRIM(msg), 1)
    END IF

    !--- INTERPOLATE 3D FIELD IF NEEDED
    IF(var/='tpot') CALL start_inter_3d(TRIM(vname), lon_in, lat_in, lon_in2, &
            lat_in2, pls, champ)

    !--- COMPUTE THE REQUIRED FILED
    SELECT CASE(var)
    CASE('u'); DO il = 1, lml; champ(:, :, il) = champ(:, :, il) * cu(:, 1:jml);
    END DO
    champ(iml, :, :) = champ(1, :, :)                   !--- Eastward wind

    CASE('v'); DO il = 1, lml; champ(:, :, il) = champ(:, :, il) * cv(:, 1:jml);
    END DO
    champ(iml, :, :) = champ(1, :, :)                   !--- Northward wind

    CASE('tpot', 'q')
      IF(var=='tpot') THEN; champ = champ * cpp / workvar !--- Potential temperature
      ELSE;                 champ = champ * .01 * workvar !--- Relative humidity
      WHERE(champ<0.) champ = 1.0E-10
      END IF
      DO il = 1, lml
        xppn = SUM(aire(:, 1) * champ(:, 1, il)) / apoln
        xpps = SUM(aire(:, jml) * champ(:, jml, il)) / apols
        champ(:, 1, il) = xppn
        champ(:, jml, il) = xpps
      END DO
    END SELECT

  END SUBROUTINE startget_dyn3d

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


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

  SUBROUTINE start_init_dyn(lon_in, lat_in, lon_in2, lat_in2, zs, psol)

    !-------------------------------------------------------------------------------
    IMPLICIT NONE
    !===============================================================================
    ! Purpose:   Compute psol, knowing phis.
    !===============================================================================
    ! Arguments:
    REAL, INTENT(IN) :: lon_in (:), lat_in (:)    ! dim (iml) (jml)
    REAL, INTENT(IN) :: lon_in2(:), lat_in2(:)    ! dim (iml) (jml2)
    REAL, INTENT(IN) :: zs  (:, :)                  ! dim (iml,jml)
    REAL, INTENT(OUT) :: psol(:, :)                  ! dim (iml,jml)
    !-------------------------------------------------------------------------------
    ! Local variables:
    CHARACTER(LEN = 256) :: modname = 'start_init_dyn'
    REAL :: date, dt
    INTEGER :: iml, jml, jml2, itau(1)
    REAL, ALLOCATABLE :: lon_rad(:), lon_ini(:), var_ana(:, :)
    REAL, ALLOCATABLE :: lat_rad(:), lat_ini(:)
    REAL, ALLOCATABLE :: z(:, :), ps(:, :), ts(:, :)
    !-------------------------------------------------------------------------------
    iml = assert_eq(SIZE(lon_in), SIZE(zs, 1), SIZE(psol, 1), SIZE(lon_in2), &
            TRIM(modname) // " iml")
    jml = assert_eq(SIZE(lat_in), SIZE(zs, 2), SIZE(psol, 2), TRIM(modname) // " jml")
    jml2 = SIZE(lat_in2)

    WRITE(lunout, *) 'Opening the surface analysis'
    CALL flininfo(dynfname, iml_dyn, jml_dyn, llm_dyn, ttm_dyn, fid_dyn)
    WRITE(lunout, *) 'Values read: ', iml_dyn, jml_dyn, llm_dyn, ttm_dyn

    ALLOCATE(lon_dyn(iml_dyn, jml_dyn), lat_dyn(iml_dyn, jml_dyn))
    ALLOCATE(levdyn_ini(llm_dyn))
    CALL flinopen(dynfname, .FALSE., iml_dyn, jml_dyn, llm_dyn, &
            lon_dyn, lat_dyn, levdyn_ini, ttm_dyn, itau, date, dt, fid_dyn)

    !--- IF ANGLES ARE IN DEGREES, THEY ARE CONVERTED INTO RADIANS
    ALLOCATE(lon_ini(iml_dyn), lat_ini(jml_dyn))
    lon_ini(:) = lon_dyn(:, 1); IF(MAXVAL(lon_dyn)>pi) lon_ini = lon_ini * deg2rad
    lat_ini(:) = lat_dyn(1, :); IF(MAXVAL(lat_dyn)>pi) lat_ini = lat_ini * deg2rad

    ALLOCATE(var_ana(iml_dyn, jml_dyn), lon_rad(iml_dyn), lat_rad(jml_dyn))
    CALL get_var_dyn('Z', z)                        !--- SURFACE GEOPOTENTIAL
    CALL get_var_dyn('SP', ps)                      !--- SURFACE PRESSURE
    CALL get_var_dyn('ST', ts)                      !--- SURFACE TEMPERATURE
    !  CALL flinclo(fid_dyn)
    DEALLOCATE(var_ana, lon_rad, lat_rad, lon_ini, lat_ini)

    !--- PSOL IS COMPUTED IN PASCALS
    psol(:iml - 1, :) = ps(:iml - 1, :) * (1.0 + (z(:iml - 1, :) - zs(:iml - 1, :)) / 287.0          &
            / ts(:iml - 1, :))
    psol(iml, :) = psol(1, :)
    DEALLOCATE(z, ps, ts)
    psol(:, 1) = SUM(aire(1:iml - 1, 1) * psol(1:iml - 1, 1)) / apoln  !--- NORTH POLE
    psol(:, jml) = SUM(aire(1:iml - 1, jml) * psol(1:iml - 1, jml)) / apols  !--- SOUTH POLE

  CONTAINS

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

    SUBROUTINE get_var_dyn(title, field)

      !-------------------------------------------------------------------------------
      USE conf_dat_m, ONLY: conf_dat2d
      IMPLICIT NONE
      !-------------------------------------------------------------------------------
      ! Arguments:
      CHARACTER(LEN = *), INTENT(IN) :: title
      REAL, ALLOCATABLE, INTENT(INOUT) :: field(:, :)
      !-------------------------------------------------------------------------------
      ! Local variables:
      CHARACTER(LEN = 256) :: msg
      INTEGER :: tllm
      !-------------------------------------------------------------------------------
      SELECT CASE(title)
      CASE('Z');     tllm = 0;       msg = 'geopotential'
      CASE('SP');    tllm = 0;       msg = 'surface pressure'
      CASE('ST');    tllm = llm_dyn; msg = 'temperature'
      END SELECT
      IF(.NOT.ALLOCATED(field)) THEN
        ALLOCATE(field(iml, jml))
        CALL flinget(fid_dyn, title, iml_dyn, jml_dyn, tllm, ttm_dyn, 1, 1, var_ana)
        CALL conf_dat2d(title, lon_ini, lat_ini, lon_rad, lat_rad, var_ana, .TRUE.)
        CALL interp_startvar(title, .TRUE., lon_rad, lat_rad, var_ana, &
                lon_in, lat_in, lon_in2, lat_in2, field)
      ELSE IF(SIZE(field)/=SIZE(z)) THEN
        msg = 'The ' // TRIM(msg) // ' field we have does not have the right size'
        CALL abort_gcm(TRIM(modname), msg, 1)
      END IF

    END SUBROUTINE get_var_dyn

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

  END SUBROUTINE start_init_dyn

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


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

  SUBROUTINE start_inter_3d(var, lon_in, lat_in, lon_in2, lat_in2, pls_in, var3d)

    !-------------------------------------------------------------------------------
    USE conf_dat_m, ONLY: conf_dat3d
    USE lmdz_libmath_pch, ONLY: pchsp_95, pchfe_95
    USE lmdz_libmath, ONLY: minmax


    IMPLICIT NONE
    !-------------------------------------------------------------------------------
    ! Arguments:
    CHARACTER(LEN = *), INTENT(IN) :: var
    REAL, INTENT(IN) :: lon_in(:), lat_in(:)   ! dim (iml) (jml)
    REAL, INTENT(IN) :: lon_in2(:), lat_in2(:)  ! dim (iml) (jml2)
    REAL, INTENT(IN) :: pls_in(:, :, :)           ! dim (iml,jml,lml)
    REAL, INTENT(OUT) :: var3d (:, :, :)           ! dim (iml,jml,lml)
    !-------------------------------------------------------------------------------
    ! Local variables:
    CHARACTER(LEN = 256) :: modname = 'start_inter_3d'
    LOGICAL :: skip
    REAL :: chmin, chmax
    INTEGER :: iml, jml, lml, jml2, ii, ij, il, ierr
    INTEGER :: n_extrap                             ! Extrapolated points number
    REAL, ALLOCATABLE :: ax(:), lon_rad(:), lon_ini(:), lev_dyn(:), yder(:)
    REAL, ALLOCATABLE :: ay(:), lat_rad(:), lat_ini(:), var_tmp3d(:, :, :)
    REAL, ALLOCATABLE, SAVE :: var_ana3d(:, :, :)
    !-------------------------------------------------------------------------------
    iml = assert_eq(SIZE(lon_in), SIZE(lon_in2), SIZE(pls_in, 1), SIZE(var3d, 1), TRIM(modname) // " iml")
    jml = assert_eq(SIZE(lat_in), SIZE(pls_in, 2), SIZE(var3d, 2), TRIM(modname) // " jml")
    lml = assert_eq(SIZE(pls_in, 3), SIZE(var3d, 3), TRIM(modname) // " lml"); jml2 = SIZE(lat_in2)

    WRITE(lunout, *)'Going into flinget to extract the 3D field.'
    IF(.NOT.ALLOCATED(var_ana3d)) ALLOCATE(var_ana3d(iml_dyn, jml_dyn, llm_dyn))
    CALL flinget(fid_dyn, var, iml_dyn, jml_dyn, llm_dyn, ttm_dyn, 1, 1, var_ana3d)

    !--- ANGLES IN DEGREES ARE CONVERTED INTO RADIANS
    ALLOCATE(lon_ini(iml_dyn), lat_ini(jml_dyn))
    lon_ini(:) = lon_dyn(:, 1); IF(MAXVAL(lon_dyn)>pi) lon_ini = lon_ini * deg2rad
    lat_ini(:) = lat_dyn(1, :); IF(MAXVAL(lat_dyn)>pi) lat_ini = lat_ini * deg2rad

    !--- FIELDS ARE PROCESSED TO BE ON STANDARD ANGULAR DOMAINS
    ALLOCATE(lon_rad(iml_dyn), lat_rad(jml_dyn), lev_dyn(llm_dyn))
    CALL conf_dat3d(var, lon_ini, lat_ini, levdyn_ini, &
            lon_rad, lat_rad, lev_dyn, var_ana3d, .TRUE.)
    DEALLOCATE(lon_ini, lat_ini)

    !--- COMPUTE THE REQUIRED FIELDS USING ROUTINE grid_noro
    ALLOCATE(var_tmp3d(iml, jml, llm_dyn))
    DO il = 1, llm_dyn
      CALL interp_startvar(var, il==1, lon_rad, lat_rad, var_ana3d(:, :, il), &
              lon_in, lat_in, lon_in2, lat_in2, var_tmp3d(:, :, il))
    END DO
    DEALLOCATE(lon_rad, lat_rad)

    !--- VERTICAL INTERPOLATION FROM TOP OF ATMOSPHERE TO GROUND
    ALLOCATE(ax(llm_dyn), ay(llm_dyn), yder(llm_dyn))
    ax = lev_dyn(llm_dyn:1:-1)
    skip = .FALSE.
    n_extrap = 0
    DO ij = 1, jml
      DO ii = 1, iml - 1
        ay = var_tmp3d(ii, ij, llm_dyn:1:-1)
        yder = pchsp_95(ax, ay, ibeg = 2, iend = 2, vc_beg = 0., vc_end = 0.)
        CALL pchfe_95(ax, ay, yder, skip, pls_in(ii, ij, lml:1:-1), &
                var3d(ii, ij, lml:1:-1), ierr)
        IF(ierr<0) CALL abort_gcm(TRIM(modname), 'error in pchfe_95', 1)
        n_extrap = n_extrap + ierr
      END DO
    END DO
    IF(n_extrap/=0) WRITE(lunout, *)TRIM(modname) // " pchfe_95: n_extrap=", n_extrap
    var3d(iml, :, :) = var3d(1, :, :)

  END SUBROUTINE start_inter_3d

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


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

  SUBROUTINE interp_startvar(nam, ibeg, lon, lat, vari, lon1, lat1, lon2, lat2, varo)

    !-------------------------------------------------------------------------------
    USE inter_barxy_m, ONLY: inter_barxy
    IMPLICIT NONE
    !-------------------------------------------------------------------------------
    ! Arguments:
    CHARACTER(LEN = *), INTENT(IN) :: nam
    LOGICAL, INTENT(IN) :: ibeg
    REAL, INTENT(IN) :: lon(:), lat(:)   ! dim (ii) (jj)
    REAL, INTENT(IN) :: vari(:, :)        ! dim (ii,jj)
    REAL, INTENT(IN) :: lon1(:), lat1(:) ! dim (i1) (j1)
    REAL, INTENT(IN) :: lon2(:), lat2(:) ! dim (i1) (j2)
    REAL, INTENT(OUT) :: varo(:, :)        ! dim (i1) (j1)
    !-------------------------------------------------------------------------------
    ! Local variables:
    CHARACTER(LEN = 256) :: modname = "interp_startvar"
    INTEGER :: ii, jj, i1, j1, j2
    REAL, ALLOCATABLE :: vtmp(:, :)
    !-------------------------------------------------------------------------------
    ii = assert_eq(SIZE(lon), SIZE(vari, 1), TRIM(modname) // " ii")
    jj = assert_eq(SIZE(lat), SIZE(vari, 2), TRIM(modname) // " jj")
    i1 = assert_eq(SIZE(lon1), SIZE(lon2), SIZE(varo, 1), TRIM(modname) // " i1")
    j1 = assert_eq(SIZE(lat1), SIZE(varo, 2), TRIM(modname) // " j1")
    j2 = SIZE(lat2)
    ALLOCATE(vtmp(i1 - 1, j1))
    IF(ibeg.AND.prt_level>1) THEN
      WRITE(lunout, *)"---------------------------------------------------------"
      WRITE(lunout, *)"$$$ Interpolation barycentrique pour " // TRIM(nam) // " $$$"
      WRITE(lunout, *)"---------------------------------------------------------"
    END IF
    CALL inter_barxy(lon, lat(:jj - 1), vari, lon2(:i1 - 1), lat2, vtmp)
    CALL gr_int_dyn(vtmp, varo, i1 - 1, j1)

  END SUBROUTINE interp_startvar

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

END MODULE etat0dyn

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