MODULE limcons !!====================================================================== !! *** MODULE limcons *** !! LIM-3 Sea Ice : conservation check !!====================================================================== !! History : - ! Original code from William H. Lipscomb, LANL !! 3.0 ! 2004-06 (M. Vancoppenolle) Energy Conservation !! 3.5 ! 2011-02 (G. Madec) add mpp considerations !! - ! 2014-05 (C. Rousset) add lim_cons_hsm !! - ! 2015-03 (C. Rousset) add lim_cons_final !!---------------------------------------------------------------------- #if defined key_lim3 !!---------------------------------------------------------------------- !! 'key_lim3' LIM-3 sea-ice model !!---------------------------------------------------------------------- !! lim_cons : checks whether energy, mass and salt are conserved !!---------------------------------------------------------------------- USE phycst ! physical constants USE ice ! LIM-3 variables USE dom_ice ! LIM-3 domain USE dom_oce ! ocean domain USE in_out_manager ! I/O manager USE lib_mpp ! MPP library USE lib_fortran ! Fortran utilities (allows no signed zero when 'key_nosignedzero' defined) USE sbc_oce , ONLY : sfx ! Surface boundary condition: ocean fields USE sbc_ice , ONLY : qevap_ice IMPLICIT NONE PRIVATE PUBLIC lim_column_sum PUBLIC lim_column_sum_energy PUBLIC lim_cons_check PUBLIC lim_cons_hsm PUBLIC lim_cons_final !!---------------------------------------------------------------------- !! NEMO/LIM3 4.0 , UCL - NEMO Consortium (2011) !! $Id: limcons.F90 4873 2014-11-18 17:53:04Z clem $ !! Software governed by the CeCILL licence (NEMOGCM/NEMO_CeCILL.txt) !!---------------------------------------------------------------------- CONTAINS SUBROUTINE lim_column_sum( ksum, pin, pout ) !!------------------------------------------------------------------- !! *** ROUTINE lim_column_sum *** !! !! ** Purpose : Compute the sum of xin over nsum categories !! !! ** Method : Arithmetics !! !! ** Action : Gets xin(ji,jj,jl) and computes xout(ji,jj) !!--------------------------------------------------------------------- INTEGER , INTENT(in ) :: ksum ! number of categories/layers REAL(wp), DIMENSION(:,:,:), INTENT(in ) :: pin ! input field REAL(wp), DIMENSION(:,:) , INTENT( out) :: pout ! output field ! INTEGER :: jl ! dummy loop indices !!--------------------------------------------------------------------- ! pout(:,:) = pin(:,:,1) DO jl = 2, ksum pout(:,:) = pout(:,:) + pin(:,:,jl) END DO ! END SUBROUTINE lim_column_sum SUBROUTINE lim_column_sum_energy( ksum, klay, pin, pout) !!------------------------------------------------------------------- !! *** ROUTINE lim_column_sum_energy *** !! !! ** Purpose : Compute the sum of xin over nsum categories !! and nlay layers !! !! ** Method : Arithmetics !!--------------------------------------------------------------------- INTEGER , INTENT(in ) :: ksum !: number of categories INTEGER , INTENT(in ) :: klay !: number of vertical layers REAL(wp), DIMENSION(jpi,jpj,nlay_i,jpl), INTENT(in ) :: pin !: input field REAL(wp), DIMENSION(jpi,jpj) , INTENT( out) :: pout !: output field ! INTEGER :: jk, jl ! dummy loop indices !!--------------------------------------------------------------------- ! pout(:,:) = 0._wp DO jl = 1, ksum DO jk = 2, klay pout(:,:) = pout(:,:) + pin(:,:,jk,jl) END DO END DO ! END SUBROUTINE lim_column_sum_energy SUBROUTINE lim_cons_check( px1, px2, pmax_err, cd_fieldid ) !!------------------------------------------------------------------- !! *** ROUTINE lim_cons_check *** !! !! ** Purpose : Test the conservation of a certain variable !! For each physical grid cell, check that initial !! and final values !! of a conserved field are equal to within a small value. !! !! ** Method : !!--------------------------------------------------------------------- REAL(wp), DIMENSION(:,:), INTENT(in ) :: px1 !: initial field REAL(wp), DIMENSION(:,:), INTENT(in ) :: px2 !: final field REAL(wp) , INTENT(in ) :: pmax_err !: max allowed error CHARACTER(len=15) , INTENT(in ) :: cd_fieldid !: field identifyer ! INTEGER :: ji, jj ! dummy loop indices INTEGER :: inb_error ! number of g.c where there is a cons. error LOGICAL :: llconserv_err ! = .true. if conservation check failed REAL(wp) :: zmean_error ! mean error on error points !!--------------------------------------------------------------------- ! IF(lwp) WRITE(numout,*) ' lim_cons_check ' IF(lwp) WRITE(numout,*) ' ~~~~~~~~~~~~~~ ' llconserv_err = .FALSE. inb_error = 0 zmean_error = 0._wp IF( MAXVAL( px2(:,:) - px1(:,:) ) > pmax_err ) llconserv_err = .TRUE. IF( llconserv_err ) THEN DO jj = 1, jpj DO ji = 1, jpi IF( ABS( px2(ji,jj) - px1(ji,jj) ) > pmax_err ) THEN inb_error = inb_error + 1 zmean_error = zmean_error + ABS( px2(ji,jj) - px1(ji,jj) ) ! IF(lwp) THEN WRITE (numout,*) ' ALERTE 99 ' WRITE (numout,*) ' Conservation error: ', cd_fieldid WRITE (numout,*) ' Point : ', ji, jj WRITE (numout,*) ' lat, lon : ', gphit(ji,jj), glamt(ji,jj) WRITE (numout,*) ' Initial value : ', px1(ji,jj) WRITE (numout,*) ' Final value : ', px2(ji,jj) WRITE (numout,*) ' Difference : ', px2(ji,jj) - px1(ji,jj) ENDIF ENDIF END DO END DO ! ENDIF IF(lk_mpp) CALL mpp_sum( inb_error ) IF(lk_mpp) CALL mpp_sum( zmean_error ) ! IF( inb_error > 0 .AND. lwp ) THEN zmean_error = zmean_error / REAL( inb_error, wp ) WRITE(numout,*) ' Conservation check for : ', cd_fieldid WRITE(numout,*) ' Number of error points : ', inb_error WRITE(numout,*) ' Mean error on these pts: ', zmean_error ENDIF ! END SUBROUTINE lim_cons_check SUBROUTINE lim_cons_hsm( icount, cd_routine, zvi_b, zsmv_b, zei_b, zfw_b, zfs_b, zft_b ) !!-------------------------------------------------------------------------------------------------------- !! *** ROUTINE lim_cons_hsm *** !! !! ** Purpose : Test the conservation of heat, salt and mass for each ice routine !! + test if ice concentration and volume are > 0 !! !! ** Method : This is an online diagnostics which can be activated with ln_limdiahsb=true !! It prints in ocean.output if there is a violation of conservation at each time-step !! The thresholds (zv_sill, zs_sill, zh_sill) which determine violations are set to !! a minimum of 1 mm of ice (over the ice area) that is lost/gained spuriously during 100 years. !! For salt and heat thresholds, ice is considered to have a salinity of 10 !! and a heat content of 3e5 J/kg (=latent heat of fusion) !!-------------------------------------------------------------------------------------------------------- INTEGER , INTENT(in) :: icount ! determine wether this is the beggining of the routine (0) or the end (1) CHARACTER(len=*), INTENT(in) :: cd_routine ! name of the routine REAL(wp) , INTENT(inout) :: zvi_b, zsmv_b, zei_b, zfs_b, zfw_b, zft_b REAL(wp) :: zvi, zsmv, zei, zfs, zfw, zft REAL(wp) :: zvmin, zamin, zamax REAL(wp) :: zvtrp, zetrp REAL(wp) :: zarea, zv_sill, zs_sill, zh_sill REAL(wp), PARAMETER :: zconv = 1.e-9 ! convert W to GW and kg to Mt IF( icount == 0 ) THEN ! salt flux zfs_b = glob_sum( ( sfx_bri(:,:) + sfx_bog(:,:) + sfx_bom(:,:) + sfx_sum(:,:) + sfx_sni(:,:) + & & sfx_opw(:,:) + sfx_res(:,:) + sfx_dyn(:,:) + sfx_sub(:,:) & & ) * e12t(:,:) * tmask(:,:,1) * zconv ) ! water flux zfw_b = glob_sum( -( wfx_bog(:,:) + wfx_bom(:,:) + wfx_sum(:,:) + wfx_sni(:,:) + wfx_opw(:,:) + & & wfx_res(:,:) + wfx_dyn(:,:) + wfx_snw(:,:) + wfx_sub(:,:) + wfx_spr(:,:) & & ) * e12t(:,:) * tmask(:,:,1) * zconv ) ! heat flux zft_b = glob_sum( ( hfx_sum(:,:) + hfx_bom(:,:) + hfx_bog(:,:) + hfx_dif(:,:) + hfx_opw(:,:) + hfx_snw(:,:) & & - hfx_thd(:,:) - hfx_dyn(:,:) - hfx_res(:,:) - hfx_sub(:,:) - hfx_spr(:,:) & & ) * e12t(:,:) * tmask(:,:,1) * zconv ) zvi_b = glob_sum( SUM( v_i * rhoic + v_s * rhosn, dim=3 ) * e12t * tmask(:,:,1) * zconv ) zsmv_b = glob_sum( SUM( smv_i * rhoic , dim=3 ) * e12t * tmask(:,:,1) * zconv ) zei_b = glob_sum( ( SUM( SUM( e_i(:,:,1:nlay_i,:), dim=4 ), dim=3 ) + & & SUM( SUM( e_s(:,:,1:nlay_s,:), dim=4 ), dim=3 ) & ) * e12t * tmask(:,:,1) * zconv ) ELSEIF( icount == 1 ) THEN ! salt flux zfs = glob_sum( ( sfx_bri(:,:) + sfx_bog(:,:) + sfx_bom(:,:) + sfx_sum(:,:) + sfx_sni(:,:) + & & sfx_opw(:,:) + sfx_res(:,:) + sfx_dyn(:,:) + sfx_sub(:,:) & & ) * e12t(:,:) * tmask(:,:,1) * zconv ) - zfs_b ! water flux zfw = glob_sum( -( wfx_bog(:,:) + wfx_bom(:,:) + wfx_sum(:,:) + wfx_sni(:,:) + wfx_opw(:,:) + & & wfx_res(:,:) + wfx_dyn(:,:) + wfx_snw(:,:) + wfx_sub(:,:) + wfx_spr(:,:) & & ) * e12t(:,:) * tmask(:,:,1) * zconv ) - zfw_b ! heat flux zft = glob_sum( ( hfx_sum(:,:) + hfx_bom(:,:) + hfx_bog(:,:) + hfx_dif(:,:) + hfx_opw(:,:) + hfx_snw(:,:) & & - hfx_thd(:,:) - hfx_dyn(:,:) - hfx_res(:,:) - hfx_sub(:,:) - hfx_spr(:,:) & & ) * e12t(:,:) * tmask(:,:,1) * zconv ) - zft_b ! outputs zvi = ( ( glob_sum( SUM( v_i * rhoic + v_s * rhosn, dim=3 ) & & * e12t * tmask(:,:,1) * zconv ) - zvi_b ) * r1_rdtice - zfw ) * rday zsmv = ( ( glob_sum( SUM( smv_i * rhoic , dim=3 ) & & * e12t * tmask(:,:,1) * zconv ) - zsmv_b ) * r1_rdtice + zfs ) * rday zei = glob_sum( ( SUM( SUM( e_i(:,:,1:nlay_i,:), dim=4 ), dim=3 ) + & & SUM( SUM( e_s(:,:,1:nlay_s,:), dim=4 ), dim=3 ) & & ) * e12t * tmask(:,:,1) * zconv ) * r1_rdtice - zei_b * r1_rdtice + zft ! zvtrp and zetrp must be close to 0 if the advection scheme is conservative zvtrp = glob_sum( ( diag_trp_vi * rhoic + diag_trp_vs * rhosn ) * e12t * tmask(:,:,1) * zconv ) * rday zetrp = glob_sum( ( diag_trp_ei + diag_trp_es ) * e12t * tmask(:,:,1) * zconv ) zvmin = glob_min( v_i ) zamax = glob_max( SUM( a_i, dim=3 ) ) zamin = glob_min( a_i ) ! set threshold values and calculate the ice area (+epsi10 to set a threshold > 0 when there is no ice) zarea = glob_sum( SUM( a_i + epsi10, dim=3 ) * e12t * zconv ) ! in 1.e9 m2 zv_sill = zarea * 2.5e-5 zs_sill = zarea * 25.e-5 zh_sill = zarea * 10.e-5 IF(lwp) THEN IF ( ABS( zvi ) > zv_sill ) WRITE(numout,*) 'violation volume [Mt/day] (',cd_routine,') = ',zvi IF ( ABS( zsmv ) > zs_sill ) WRITE(numout,*) 'violation saline [psu*Mt/day] (',cd_routine,') = ',zsmv IF ( ABS( zei ) > zh_sill ) WRITE(numout,*) 'violation enthalpy [GW] (',cd_routine,') = ',zei IF ( ABS(zvtrp ) > zv_sill .AND. cd_routine == 'limtrp' ) THEN WRITE(numout,*) 'violation vtrp [Mt/day] (',cd_routine,') = ',zvtrp WRITE(numout,*) 'violation etrp [GW] (',cd_routine,') = ',zetrp ENDIF IF ( zvmin < -epsi10 ) WRITE(numout,*) 'violation v_i<0 [m] (',cd_routine,') = ',zvmin IF ( zamax > MAX( rn_amax_n, rn_amax_s ) + epsi10 .AND. & & cd_routine /= 'limtrp' .AND. cd_routine /= 'limitd_me' ) THEN WRITE(numout,*) 'violation a_i>amax (',cd_routine,') = ',zamax ENDIF IF ( zamin < -epsi10 ) WRITE(numout,*) 'violation a_i<0 (',cd_routine,') = ',zamin ENDIF ENDIF END SUBROUTINE lim_cons_hsm SUBROUTINE lim_cons_final( cd_routine ) !!--------------------------------------------------------------------------------------------------------- !! *** ROUTINE lim_cons_final *** !! !! ** Purpose : Test the conservation of heat, salt and mass at the end of each ice time-step !! !! ** Method : This is an online diagnostics which can be activated with ln_limdiahsb=true !! It prints in ocean.output if there is a violation of conservation at each time-step !! The thresholds (zv_sill, zs_sill, zh_sill) which determine the violation are set to !! a minimum of 1 mm of ice (over the ice area) that is lost/gained spuriously during 100 years. !! For salt and heat thresholds, ice is considered to have a salinity of 10 !! and a heat content of 3e5 J/kg (=latent heat of fusion) !!-------------------------------------------------------------------------------------------------------- CHARACTER(len=*), INTENT(in) :: cd_routine ! name of the routine REAL(wp) :: zhfx, zsfx, zvfx REAL(wp) :: zarea, zv_sill, zs_sill, zh_sill REAL(wp), PARAMETER :: zconv = 1.e-9 ! convert W to GW and kg to Mt #if ! defined key_bdy ! heat flux zhfx = glob_sum( ( hfx_in - hfx_out - diag_heat - diag_trp_ei - diag_trp_es & ! & - SUM( qevap_ice * a_i_b, dim=3 ) & !!clem: I think this line must be commented (but need check) & ) * e12t * tmask(:,:,1) * zconv ) ! salt flux zsfx = glob_sum( ( sfx + diag_smvi ) * e12t * tmask(:,:,1) * zconv ) * rday ! water flux zvfx = glob_sum( ( wfx_ice + wfx_snw + wfx_spr + wfx_sub + diag_vice + diag_vsnw ) * e12t * tmask(:,:,1) * zconv ) * rday ! set threshold values and calculate the ice area (+epsi10 to set a threshold > 0 when there is no ice) zarea = glob_sum( SUM( a_i + epsi10, dim=3 ) * e12t * zconv ) ! in 1.e9 m2 zv_sill = zarea * 2.5e-5 zs_sill = zarea * 25.e-5 zh_sill = zarea * 10.e-5 IF( ABS( zvfx ) > zv_sill ) WRITE(numout,*) 'violation vfx [Mt/day] (',cd_routine,') = ',(zvfx) IF( ABS( zsfx ) > zs_sill ) WRITE(numout,*) 'violation sfx [psu*Mt/day] (',cd_routine,') = ',(zsfx) IF( ABS( zhfx ) > zh_sill ) WRITE(numout,*) 'violation hfx [GW] (',cd_routine,') = ',(zhfx) #endif END SUBROUTINE lim_cons_final #else !!---------------------------------------------------------------------- !! Default option Empty module NO LIM sea-ice model !!---------------------------------------------------------------------- #endif !!====================================================================== END MODULE limcons