source: branches/2015/dev_r5003_MERCATOR6_CRS/NEMOGCM/NEMO/OPA_SRC/CRS/crsfld.F90 @ 8092

MODULE crsfld
   !!======================================================================
   !!                     ***  MODULE  crsdfld  ***
   !!  Ocean coarsening :  coarse ocean fields
   !!=====================================================================
   !!   2012-07  (J. Simeon, C. Calone, G. Madec, C. Ethe)
   !!----------------------------------------------------------------------

   !!----------------------------------------------------------------------
   !!   crs_fld       : create the standard output files for coarse grid and prep
   !!                       other variables needed to be passed to TOP
   !!----------------------------------------------------------------------
   USE oce             ! ocean dynamics and tracers 
   USE dom_oce         ! ocean space and time domain
   USE ldftra_oce      ! ocean active tracers: lateral physics
   USE sbc_oce         ! Surface boundary condition: ocean fields
   USE sbcrnf
   USE zdf_oce         ! vertical  physics: ocean fields
   USE zdfddm          ! vertical  physics: double diffusion
   USe zdfmxl
   USE lbclnk          ! ocean lateral boundary conditions (or mpp link)
   USE in_out_manager  ! I/O manager
   USE timing          ! preformance summary
   USE wrk_nemo        ! working array
   USE crs
   USE crsdom
   USE domvvl
   USE crslbclnk
   USE iom
   USE zdfmxl_crs
   USE eosbn2
   USE zdftke

   USE ieee_arithmetic

   IMPLICIT NONE
   PRIVATE

   PUBLIC   crs_fld                 ! routines called by step.F90


   !! * Substitutions
#  include "zdfddm_substitute.h90"
#  include "domzgr_substitute.h90"
#  include "vectopt_loop_substitute.h90"
   !!----------------------------------------------------------------------
   !! NEMO/OPA 3.3 , NEMO Consortium (2010)
   !! $Id $
   !! Software governed by the CeCILL licence     (NEMOGCM/NEMO_CeCILL.txt)
   !!----------------------------------------------------------------------
CONTAINS

   SUBROUTINE crs_fld( kt )
      !!---------------------------------------------------------------------
      !!                  ***  ROUTINE crs_fld  ***
      !!                   
      !! ** Purpose :   Basic output of coarsened dynamics and tracer fields 
      !!      NETCDF format is used by default 
      !!      1. Accumulate in time the dimensionally-weighted fields
      !!      2. At time of output, rescale [1] by dimension and time
      !!         to yield the spatial and temporal average.
      !!
      !! ** Method  :  
      !!----------------------------------------------------------------------
      !!
      INTEGER, INTENT( in ) ::   kt      ! ocean time-step index
      !!
      INTEGER                             :: ji, jj, jk              ! dummy loop indices
      REAL(wp)                            :: z2dcrsu, z2dcrsv
      REAL(wp)                            :: z1_2dt
      REAL(wp), POINTER, DIMENSION(:,:,:) :: zfse3t, zfse3u, zfse3v, zfse3w ! 3D workspace for e3
      REAL(wp), POINTER, DIMENSION(:,:,:) :: zt, zs , ztmp
      REAL(wp), POINTER, DIMENSION(:,:)   :: z2d,z2d_crs
      REAL(wp), POINTER, DIMENSION(:,:,:) :: zt_crs, zs_crs
      !!----------------------------------------------------------------------

      IF( nn_timing == 1 )   CALL timing_start('crs_fld')

      !  Initialize arrays
      CALL wrk_alloc( jpi, jpj, jpk, zfse3t, zfse3w )
      CALL wrk_alloc( jpi, jpj, jpk, zfse3u, zfse3v )
      CALL wrk_alloc( jpi, jpj, jpk, zt, zs , ztmp        )
      CALL wrk_alloc( jpi, jpj,      z2d            )
      !
      CALL wrk_alloc( jpi_crs, jpj_crs, jpk, zt_crs, zs_crs )
      CALL wrk_alloc( jpi_crs, jpj_crs, z2d_crs     )

      CALL iom_swap( "nemo_crs" )    ! swap on the coarse grid

      !---------------------------------------------------------------------------------------------------
      !scale factors: before and now 
      !---------------------------------------------------------------------------------------------------
#if defined key_vvl
 

      IF( kt /= nit000 )THEN
         zfse3t(:,:,:) = e3t_b(:,:,:)
         zfse3u(:,:,:) = e3u_b(:,:,:)
         zfse3v(:,:,:) = e3v_b(:,:,:)
         zfse3w(:,:,:) = e3w_b(:,:,:)

         CALL crs_dom_e3( e1t, e2t, zfse3t, p_sfc_3d_crs=e1e2w_crs, cd_type='T', p_mask=tmask, p_e3_crs=e3t_b_crs, p_e3_max_crs=zs_crs)
         CALL crs_dom_e3( e1t, e2t, zfse3w, p_sfc_3d_crs=e1e2w_crs, cd_type='W', p_mask=tmask, p_e3_crs=e3w_b_crs, p_e3_max_crs=zs_crs)
         CALL crs_dom_e3( e1u, e2u, zfse3u, p_sfc_2d_crs=e2u_crs  , cd_type='U', p_mask=umask, p_e3_crs=e3u_b_crs, p_e3_max_crs=zs_crs)
         CALL crs_dom_e3( e1v, e2v, zfse3v, p_sfc_2d_crs=e1v_crs  , cd_type='V', p_mask=vmask, p_e3_crs=e3v_b_crs, p_e3_max_crs=zs_crs)

         DO jk = 1, jpk
            DO ji = 1, jpi_crs
               DO jj = 1, jpj_crs
                  IF( e3t_b_crs(ji,jj,jk) == 0._wp ) e3t_b_crs(ji,jj,jk) = e3t_1d(jk)
                  IF( e3w_b_crs(ji,jj,jk) == 0._wp ) e3w_b_crs(ji,jj,jk) = e3w_1d(jk)
                  IF( e3u_b_crs(ji,jj,jk) == 0._wp ) e3u_b_crs(ji,jj,jk) = e3t_1d(jk)
                  IF( e3v_b_crs(ji,jj,jk) == 0._wp ) e3v_b_crs(ji,jj,jk) = e3t_1d(jk)
               ENDDO
            ENDDO
         ENDDO

         e3t_n_crs(:,:,:) = e3t_a_crs(:,:,:)
         e3u_n_crs(:,:,:) = e3u_a_crs(:,:,:)
         e3v_n_crs(:,:,:) = e3v_a_crs(:,:,:)
         e3w_n_crs(:,:,:) = e3w_a_crs(:,:,:)

      ENDIF
#endif
      !---------------------------------------------------------------------------------------------------
      !variables domaine au temps before : swap 
      !---------------------------------------------------------------------------------------------------
#if defined key_vvl
      zfse3t(:,:,:) = e3t_b(:,:,:)
      zfse3u(:,:,:) = e3u_b(:,:,:)
      zfse3v(:,:,:) = e3v_b(:,:,:)
      zfse3w(:,:,:) = e3w_b(:,:,:)
#else
      zfse3t(:,:,:) = e3t_0(:,:,:)
      zfse3u(:,:,:) = e3u_0(:,:,:)
      zfse3v(:,:,:) = e3v_0(:,:,:)
      zfse3w(:,:,:) = e3w_0(:,:,:)
#endif

      IF( kt /= nit000 )THEN
         emp_b_crs(:,:)        = emp_crs(:,:)
         rnf_b_crs(:,:)        = rnf_crs(:,:)
      ELSE
         emp_b_crs(:,:    ) = 0._wp
         rnf_b_crs(:,:    ) = 0._wp
      ENDIF

      !  Temperature
      zt(:,:,:) = tsb(:,:,:,jp_tem)  ;      zt_crs(:,:,:) = 0._wp
      CALL crs_dom_ope( zt, 'VOL', 'T', tmask, zt_crs, p_e12=e1e2t, p_e3=zfse3t, psgn=1.0 )
      tsb_crs(:,:,:,jp_tem) = zt_crs(:,:,:)

      !  Salinity
      zs(:,:,:) = tsb(:,:,:,jp_sal)  ;      zs_crs(:,:,:) = 0._wp
      CALL crs_dom_ope( zs, 'VOL', 'T', tmask, zs_crs, p_e12=e1e2t, p_e3=zfse3t, psgn=1.0 )
      tsb_crs(:,:,:,jp_sal) = zs_crs(:,:,:)

      ! n2
      CALL crs_dom_ope( rn2b, 'VOL', 'W', tmask, rb2_crs, p_e12=e1e2t, p_e3=zfse3t, psgn=1.0 )

      !ssh
      zfse3t(:,:,:) = 1._wp
      CALL crs_dom_ope( sshb , 'VOL', 'T', tmask, sshb_crs , p_e12=e1e2t, p_e3=zfse3t         , psgn=1.0 )

      !---------------------------------------------------------------------------------------------------
      !variables at now time : 
      !---------------------------------------------------------------------------------------------------
#if defined key_vvl
      zfse3t(:,:,:) = e3t_n(:,:,:)
      zfse3u(:,:,:) = e3u_n(:,:,:)
      zfse3v(:,:,:) = e3v_n(:,:,:)
      zfse3w(:,:,:) = e3w_n(:,:,:)
      CALL iom_put("e3t",e3t_n_crs)
      CALL iom_put("e3u",e3u_n_crs)
      CALL iom_put("e3v",e3v_n_crs)
      CALL iom_put("e3w",e3w_n_crs)
#else
      zfse3t(:,:,:) = e3t_0(:,:,:)
      zfse3u(:,:,:) = e3u_0(:,:,:)
      zfse3v(:,:,:) = e3v_0(:,:,:)
      zfse3w(:,:,:) = e3w_0(:,:,:)
#endif

#if defined key_vvl

      ! surfaces
      CALL crs_dom_sfc( umask, 'U', e2e3u_crs, e2e3u_msk, p_e2=e2u, p_e3=zfse3u )
      CALL crs_dom_sfc( vmask, 'V', e1e3v_crs, e1e3v_msk, p_e1=e1v, p_e3=zfse3v )
      !cbr CALL iom_put("e2e3u_crs",e2e3u_crs)
      !CALL iom_put("e2e3u_msk",e2e3u_msk)
      !CALL iom_put("e1e3v_crs",e1e3v_crs)
      !CALL iom_put("e1e3v_msk",e1e3v_msk)

      ! vertical scale factors                                                                                 
      CALL crs_dom_e3( e1t, e2t, zfse3t, p_sfc_3d_crs=e1e2w_crs, cd_type='T', p_mask=tmask, p_e3_crs=zs_crs, p_e3_max_crs=e3t_max_n_crs)
      CALL crs_dom_e3( e1t, e2t, zfse3w, p_sfc_3d_crs=e1e2w_crs, cd_type='W', p_mask=tmask, p_e3_crs=zs_crs, p_e3_max_crs=e3w_max_n_crs)
      CALL crs_dom_e3( e1u, e2u, zfse3u, p_sfc_2d_crs=e2u_crs  , cd_type='U', p_mask=umask, p_e3_crs=zs_crs, p_e3_max_crs=e3u_max_n_crs)
      CALL crs_dom_e3( e1v, e2v, zfse3v, p_sfc_2d_crs=e1v_crs  , cd_type='V', p_mask=vmask, p_e3_crs=zs_crs, p_e3_max_crs=e3v_max_n_crs)

      DO jk = 1, jpk
         DO ji = 1, jpi_crs
            DO jj = 1, jpj_crs
               IF( e3t_max_n_crs(ji,jj,jk) == 0._wp ) e3t_max_n_crs(ji,jj,jk) = e3t_1d(jk)
               IF( e3w_max_n_crs(ji,jj,jk) == 0._wp ) e3w_max_n_crs(ji,jj,jk) = e3w_1d(jk)
               IF( e3u_max_n_crs(ji,jj,jk) == 0._wp ) e3u_max_n_crs(ji,jj,jk) = e3t_1d(jk)
               IF( e3v_max_n_crs(ji,jj,jk) == 0._wp ) e3v_max_n_crs(ji,jj,jk) = e3t_1d(jk)
            ENDDO
         ENDDO
      ENDDO

      ! depth
      CALL crs_dom_ope( gdepw_n, 'MAX', 'T', tmask, gdept_n_crs, p_e3=zfse3t, psgn=1.0 )
      CALL crs_dom_ope( gdepw_n, 'MAX', 'W', tmask, gdepw_n_crs, p_e3=zfse3w, psgn=1.0 )
      DO jk = 1, jpk
         DO ji = 1, jpi_crs
            DO jj = 1, jpj_crs
               IF( gdept_n_crs(ji,jj,jk) .LE. 0._wp ) gdept_n_crs(ji,jj,jk) = gdept_1d(jk)
               IF( gdepw_n_crs(ji,jj,jk) .LE. 0._wp ) gdepw_n_crs(ji,jj,jk) = gdepw_1d(jk)
            ENDDO
         ENDDO
      ENDDO

      ! volume and facvol
      CALL crs_dom_facvol( tmask, 'T', e1t, e2t, zfse3t, ocean_volume_crs_t, facvol_t )
      !cbr CALL iom_put("cvol_crs_t",ocean_volume_crs_t)
      !
      bt_crs(:,:,:) = ocean_volume_crs_t(:,:,:) * facvol_t(:,:,:)*tmask_crs(:,:,:)
      !
      r1_bt_crs(:,:,:) = 0._wp
      WHERE( bt_crs /= 0._wp ) r1_bt_crs(:,:,:) = 1._wp / bt_crs(:,:,:)

      CALL crs_dom_facvol( tmask, 'W', e1t, e2t, zfse3w, ocean_volume_crs_w, facvol_w )

#endif

      !  Temperature
      zt(:,:,:) = tsn(:,:,:,jp_tem)  ;      zt_crs(:,:,:) = 0._wp
      CALL crs_dom_ope( zt, 'VOL', 'T', tmask, zt_crs, p_e12=e1e2t, p_e3=zfse3t, psgn=1.0 )
      tsn_crs(:,:,:,jp_tem) = zt_crs(:,:,:)

      CALL iom_put( "toce", tsn_crs(:,:,:,jp_tem) )    ! temp
      CALL iom_put( "sst" , tsn_crs(:,:,1,jp_tem) )    ! sst

      !  Salinity
      zs(:,:,:) = tsn(:,:,:,jp_sal)  ;      zs_crs(:,:,:) = 0._wp
      CALL crs_dom_ope( zs, 'VOL', 'T', tmask, zs_crs, p_e12=e1e2t, p_e3=zfse3t, psgn=1.0 )
      tsn_crs(:,:,:,jp_sal) = zs_crs(:,:,:)

      CALL iom_put( "soce" , tsn_crs(:,:,:,jp_sal) )    ! sal
      CALL iom_put( "sss"  , tsn_crs(:,:,1,jp_sal) )    ! sss

      !  U-velocity
      CALL crs_dom_ope( un, 'SUM', 'U', umask, un_crs, p_e12=e2u, p_e3=zfse3u, p_surf_crs=e2e3u_msk, psgn=-1.0 )
      CALL iom_put( "uoce"  , un_crs )   ! i-current 

      !  V-velocity
      CALL crs_dom_ope( vn, 'SUM', 'V', vmask, vn_crs, p_e12=e1v, p_e3=zfse3v, p_surf_crs=e1e3v_msk, psgn=-1.0 )
      CALL iom_put( "voce"  , vn_crs )   ! i-current 

!      !n2
!      CALL crs_dom_ope( rn2 , 'VOL', 'W', tmask, rn2_crs, p_e12=e1e2t, p_e3=zfse3t, psgn=1.0 )
     
      !  Horizontal divergence ( following OPA_SRC/DYN/divcur.F90 ) 
      hdivn_crs(:,:,:)=0._wp
      DO jk = 1, jpkm1
         DO jj = 2,jpj_crs
            DO ji = 2,jpi_crs
               z2dcrsu =  ( un_crs(ji  ,jj  ,jk) * e2e3u_msk(ji  ,jj  ,jk) ) &
                 &      - ( un_crs(ji-1,jj  ,jk) * e2e3u_msk(ji-1,jj  ,jk) )
               z2dcrsv =  ( vn_crs(ji  ,jj  ,jk) * e1e3v_msk(ji  ,jj  ,jk) ) &
                 &      - ( vn_crs(ji  ,jj-1,jk) * e1e3v_msk(ji  ,jj-1,jk) )

               hdivn_crs(ji,jj,jk) = ( z2dcrsu + z2dcrsv )
            ENDDO
         ENDDO
      ENDDO
      CALL crs_lbc_lnk( hdivn_crs, 'T', 1.0 )
      !
      CALL iom_put( "hdiv", hdivn_crs )  


      !  avt, avs
      SELECT CASE ( nn_crs_kz )
         CASE ( 0 )
            CALL crs_dom_ope( avt, 'VOL', 'W', tmask, avt_crs, p_e12=e1e2t, p_e3=zfse3w, psgn=1.0 )
         CASE ( 1 )
            CALL crs_dom_ope( avt, 'MAX', 'W', tmask, avt_crs, p_e12=e1e2t, p_e3=zfse3w, psgn=1.0 )
         CASE ( 2 )
            CALL crs_dom_ope( avt, 'MIN', 'W', tmask, avt_crs, p_e12=e1e2t, p_e3=zfse3w, psgn=1.0 )
         CASE ( 3 )
            CALL crs_dom_ope( avt, 'LOGVOL', 'W', tmask, avt_crs, p_e12=e1e2t, p_e3=zfse3w, p_mask_crs=tmask_crs, psgn=1.0 )
         CASE ( 4 )
            CALL crs_dom_ope( avt, 'MED', 'W', tmask, avt_crs, p_e12=e1e2t, p_e3=zfse3w, psgn=1.0 )
      END SELECT
      !
      CALL iom_put( "avt", avt_crs )   !  Kz

      !2D fields
      CALL crs_dom_ope( rnf  , 'MAX', 'T', tmask, rnf_crs                                     , psgn=1.0 )
      CALL crs_dom_ope( h_rnf, 'MAX', 'T', tmask, h_rnf_crs                                   , psgn=1.0 )

      z2d=REAL(nk_rnf,wp)
      CALL crs_dom_ope( z2d  , 'MAX', 'T', tmask, z2d_crs  , p_e12=e1e2t, p_surf_crs=e1e2t_crs, psgn=1.0 )
      nk_rnf_crs=INT(z2d_crs)

      CALL crs_dom_ope( qsr  , 'SUM', 'T', tmask, qsr_crs   , p_e12=e1e2t, p_surf_crs=e1e2w_msk(:,:,1), psgn=1.0 )
      CALL crs_dom_ope( wndm , 'SUM', 'T', tmask, wndm_crs  , p_e12=e1e2t, p_surf_crs=e1e2w_msk(:,:,1), psgn=1.0 )
      CALL crs_dom_ope( emp   ,'SUM', 'T', tmask, emp_crs   , p_e12=e1e2t, p_surf_crs=e1e2w_msk(:,:,1), psgn=1.0 )
      CALL crs_dom_ope( fmmflx,'SUM', 'T', tmask, fmmflx_crs, p_e12=e1e2t, p_surf_crs=e1e2w_msk(:,:,1), psgn=1.0 )

      CALL crs_dom_ope( fr_i  ,'SUM', 'T', tmask, fr_i_crs  , p_e12=e1e2t, p_surf_crs=e1e2w_msk(:,:,1), psgn=1.0 )
      fr_i_crs=MAX( 0._wp, MIN( fr_i_crs , 1._wp ) )

      z2d=REAL(nmln,wp)
      CALL crs_dom_ope( z2d , 'MAX', 'T', tmask, z2d_crs , p_e12=e1e2t, p_surf_crs=e1e2t_crs, psgn=1.0 )
      nmln_crs=INT(z2d_crs) 
      nmln_crs=MAX(nlb10,nmln_crs)    

      CALL iom_put( "utau"     , utau_crs )   ! i-tau output 
      CALL iom_put( "vtau"     , vtau_crs )   ! j-tau output 
      CALL iom_put( "wspd"     , wndm_crs )   ! wind speed output 
      CALL iom_put( "runoffs"  , rnf_crs  )   ! runoff output 
      CALL iom_put( "qsr"      , qsr_crs  )   ! qsr output 
      CALL iom_put( "empmr"    , emp_crs  )   ! water flux output 
      CALL iom_put( "saltflx"  , fmmflx_crs  )   ! salt flux output 
      CALL iom_put( "ice_cover", fr_i_crs )   ! ice cover output 

      zfse3t(:,:,:) = 1._wp
      CALL crs_dom_ope( sshn , 'VOL', 'T', tmask, sshn_crs , p_e12=e1e2t, p_e3=zfse3t         , psgn=1.0 )  
      CALL iom_put( "ssh"      , sshn_crs )   ! ssh output 


#if defined key_vvl
      !---------------------------------------------------------------------------------------------------
      !variables au temps after
      !---------------------------------------------------------------------------------------------------

      !ssha
      zfse3t(:,:,:) = 1._wp
      zt(:,:,:) = tmask(:,:,:)
      CALL crs_dom_ope( ssha , 'VOL', 'T', zt, ssha_crs , p_e12=e1e2t,  p_e3=zfse3t , psgn=1.0 )

      !vertical scale factors
      zfse3t(:,:,:) = e3t_a(:,:,:)
      zfse3u(:,:,:) = e3u_a(:,:,:)
      zfse3v(:,:,:) = e3v_a(:,:,:)
      CALL dom_vvl_interpol( zfse3t(:,:,:), zfse3w(:,:,:), 'W'   )

      CALL crs_dom_e3( e1t, e2t, zfse3t, p_sfc_3d_crs=e1e2w_crs, cd_type='T', p_mask=tmask, p_e3_crs=e3t_a_crs, p_e3_max_crs=zs_crs)
      CALL crs_dom_e3( e1t, e2t, zfse3w, p_sfc_3d_crs=e1e2w_crs, cd_type='W', p_mask=tmask, p_e3_crs=e3w_a_crs, p_e3_max_crs=zs_crs)
      CALL crs_dom_e3( e1u, e2u, zfse3u, p_sfc_2d_crs=e2u_crs  , cd_type='U', p_mask=umask, p_e3_crs=e3u_a_crs, p_e3_max_crs=zs_crs)
      CALL crs_dom_e3( e1v, e2v, zfse3v, p_sfc_2d_crs=e1v_crs  , cd_type='V', p_mask=vmask, p_e3_crs=e3v_a_crs, p_e3_max_crs=zs_crs)

      DO jk = 1, jpk
         DO ji = 1, jpi_crs
            DO jj = 1, jpj_crs
               IF( e3t_a_crs(ji,jj,jk) == 0._wp ) e3t_a_crs(ji,jj,jk) = e3t_1d(jk)
               IF( e3w_a_crs(ji,jj,jk) == 0._wp ) e3w_a_crs(ji,jj,jk) = e3w_1d(jk)
               IF( e3u_a_crs(ji,jj,jk) == 0._wp ) e3u_a_crs(ji,jj,jk) = e3t_1d(jk)
               IF( e3v_a_crs(ji,jj,jk) == 0._wp ) e3v_a_crs(ji,jj,jk) = e3t_1d(jk)
            ENDDO
        ENDDO
      ENDDO

#endif

#if defined key_vvl

      z1_2dt = 1._wp / ( 2. * rdt )                         ! set time step size (Euler/Leapfrog)
      IF( neuler == 0 .AND. kt == nit000 )   z1_2dt = 1._wp / rdt

      wn_crs(:,:,jpk) = 0._wp
      DO jk = jpkm1, 1, -1
         wn_crs(:,:,jk) = wn_crs(:,:,jk+1)*e1e2w_msk(:,:,jk+1) - (  hdivn_crs(:,:,jk)                                   &
               &                          + z1_2dt * e1e2w_msk(:,:,jk) * ( e3t_a_crs(:,:,jk) - e3t_b_crs(:,:,jk) ) ) * tmask_crs(:,:,jk)
         WHERE( e1e2w_msk(:,:,jk) .NE. 0._wp )  wn_crs(:,:,jk) =  wn_crs(:,:,jk) /e1e2w_msk(:,:,jk)


      ENDDO
#else
      IF( ln_crs_wn ) THEN
         CALL crs_dom_ope( wn, 'SUM', 'W', tmask, wn_crs, p_e12=e1e2t, p_surf_crs=e1e2w_msk, psgn=1.0 )
      ELSE
         wn_crs(:,:,jpk) = 0._wp
         DO jk = jpkm1, 1, -1
            wn_crs(:,:,jk) = e1e2w_msk(:,:,jk+1)*wn_crs(:,:,jk+1) - hdivn_crs(:,:,jk)
            WHERE( e1e2w_msk(:,:,jk) .NE. 0._wp )  wn_crs(:,:,jk) =  wn_crs(:,:,jk) /e1e2w_msk(:,:,jk)
         ENDDO
       ENDIF

#endif
      CALL iom_put( "woce", wn_crs  )   ! vertical velocity

      !---------------------------------------------------------------------------------------------------
      !  free memory
      CALL wrk_dealloc( jpi, jpj, jpk, zfse3t, zfse3w )
      CALL wrk_dealloc( jpi, jpj, jpk, zfse3u, zfse3v )
      CALL wrk_dealloc( jpi, jpj, jpk, zt, zs, ztmp   )
      CALL wrk_dealloc( jpi, jpj, z2d                 )
      CALL wrk_dealloc( jpi_crs, jpj_crs, jpk, zt_crs, zs_crs )
      CALL wrk_dealloc( jpi_crs, jpj_crs, z2d_crs     )
      !
      CALL iom_swap( "nemo" )     ! return back on high-resolution grid
      !
      IF( nn_timing == 1 )   CALL timing_stop('crs_fld')
      !
   END SUBROUTINE crs_fld

   !!======================================================================
END MODULE crsfld