subroutine PHY_MAR & !------------------------------------------------------------------------------+ ! Mon 1-Jul-2013 MAR | ! subroutine PHY_MAR is the MAR PHYsics Driver | ! interfaces HOST variables | ! and SISVAT variables | ! | ! Applied to: MARthusalem (variables in MAR***.inc files) | ! | ! | ! # OPTIONS: #dT Distinction among Tendencies of MAR Physical Parametr. | ! # ^^^^^^^^ #cw Cloud Condensation Nuclei (CCNw) Microphysics Activation | ! | ! | ! version 3.p.4.1 created by H. Gallee, Tue 12-Mar-2013 | ! Last Modification by H. Gallee, Mon 1-Jul-2013 | ! | !------------------------------------------------------------------------------+ & (FlagSV & ! FLAG for SISVAT: (T,F) = (active OR NOT) & ,FlagSV_Veg & ! FLAG for SISVAT: (T,F) = (Variable Vegetation OR NOT) & ,FlagSV_SNo & ! FLAG for SISVAT: (T,F) = (Snow Model active OR NOT) & ,FlagSV_BSn & ! FLAG for SISVAT: (T,F) = (Blowing Snow Model active OR NOT) & ,FlagSV_KzT & ! FLAG for SISVAT: (T,F) = (pkt Turb.Transfert active OR NOT in SISVAT) & ,FlagSV_SWD & ! FLAG for SISVAT: (T,F) = (Modify SW INPUT->downward OR NOT) & ,FlagSV_SBC & ! FLAG for SISVAT: (T,F) = (INPUT of Soil & Vege DATA OR NOT in SISVAT) & ,FlagSV_UBC & ! FLAG for SISVAT: (T,F) = (pkt UpperBC is Von Neuman OR NOT in SISVAT) & ,FlagAT & ! FLAG for Atm_AT: (T,F) = (Turbulent Transfer active OR NOT) & ,TypeAT & ! TYPE of Atm_AT: (e= Ee Duynkerke, K= Ee Kitada, L= EL, H= Ee Huan-R) & ,FlagAT_TKE & ! FLAG for genTKE: (T,F) = (TKE-e Model active OR NOT) & ,FlagCM & ! FLAG for CMiPhy: (T,F) = (Cloud Microphysics active OR NOT) & ,FlagCM_UpD & ! FLAG for CMiPhy: (T,F) = (qv & hydrometeors updated OR NOT IN CMiPhy) & ,FlagCP & ! FLAG for Convection Paramet. & ,FlagRT & ! FLAG for Radiative Transfer & ,FlagS0_SLO & ! FLAG for Insolation, Surfac.Slope Impact included NEW & ,FlagS0_MtM & ! FLAG for Insolation, Surfac.Slope & Mountain Mask Impacts included NEW & ,Flag_O & ! FLAG for OUTPUT & ,FlagVR & ! FLAG for OUTPUT for VERIFICATION & ,dt0DYn & ! Time STEP between 2 CALLs of PHY_MAR [s] I, fix & ,dt0_SV & ! Time STEP between 2 CALLs of SISVAT [s] I, fix & ,dt0_AT & ! Time STEP between 2 CALLs of Atm_AT [s] I, fix & ,dt0_CM & ! Time STEP between 2 CALLs of CMiPhy [s] I, fix & ,dt0_CP & ! Time STEP between 2 CALLs of CVamnh [s] I, fix & ,dt0_RT & ! Time STEP between 2 CALLs of radCEP [s] I, fix & ,dx & ! Grid Mesh size (Horizontal) [m] I, fix & ,DD_AxX & ! Grid x-Axis Direction [degree] I, fix & ,s_HOST & ! Grid (Vertical) of HOST (NORMALIZED PRESSURE assumed) [-] I, fix & ,sh___HOST & ! Topography [m] I, fix & ,sh_a_HOST & ! Topography Anomaly [m] I, fix NEW & ,slopxHOST & ! Slope, x-direction [-] I, fix NEW & ,slopyHOST & ! Slope, y-direction [-] I, fix NEW & ,slopeHOST & ! Slope [-] I, fix NEW & ,MMaskHOST & ! Mountain Mask [-] I, fix NEW & ,lonh_HOST & ! Longitude [hour] I, fix & ,latr_HOST & ! Latitude [radian] I, fix & ,pkta_HOST & ! Reduced Potential Temperature [XK] I, O & ,ptop_HOST & ! Pressure, Model Top [kPa] I, fix & ,psa__HOST & ! Pressure Thickness [kPa] I & ,gZa__HOST & ! Geopotential Height [m2/s2] I & ,gZam_HOST & ! Geopotential Height, mid-level [m2/s2] I & ,Ua___HOST & ! Wind , x-Direction [m/s] I & ,Va___HOST & ! Wind , y-Direction [m/s] I & ,Wa___HOST & ! Wind , z-Direction [m/s] I & ,qv___HOST & ! Specific Humidity [kg/kg] I, O & ,qw___HOST & ! Cloud Droplets Concentration [kg/kg] I, O ! #cw& ,CCN__HOST & ! CCN Concentration [-/kg] & ,qi___HOST & ! Cloud Crystals Concentration [kg/kg] I, O & ,CIN__HOST & ! CIN Concentration [-/kg] I, O & ,CF___HOST & ! Cloud Fraction [-] I, O & ,qs___HOST & ! Snow Particles Concentration [kg/kg] I, O & ,qr___HOST & ! Rain Drops Concentration [kg/kg] I, O & ,TKE__HOST & ! Turbulent Kinetic Energy [m2/s2] I, O & ,eps__HOST & ! Turbulent Kinetic Energy Dissipation [m2/s3] I, O & ,dpkt___dt & ! Reduced Potential Temperature TENDENCY, ALL Contribut.[KX/s] O & ,dua____dt & ! Wind Speed (x-direc.) TENDENCY, ALL Contribut.[m/s2] O & ,dva____dt & ! Wind Speed (y-direc.) TENDENCY, ALL Contribut.[m/s2] O & ,dqv____dt & ! Specific Humidity TENDENCY, ALL Contr. [kg/kg/s] O & ,dqw____dt & ! Cloud Droplets Concentration TENDENCY, ALL Contr. [kg/kg/s] O ! #cw& ,dCw____dt & ! CCN Concentration TENDENCY, ALL Contr. [1/s] & ,dqi____dt & ! Cloud Crystals Concentration TENDENCY, ALL Contr. [kg/kg/s] O & ,dCi____dt & ! CIN Concentration TENDENCY, ALL Contr. [1/s] O & ,dCF____dt & ! Cloud Fraction TENDENCY, ALL Contr. [1/s] O & ,dqs____dt & ! Snow Particles Concentration TENDENCY, ALL Contr. [kg/kg/s] O & ,dqr____dt & ! Rain Drops Concentration TENDENCY, ALL Contr. [kg/kg/s] O ! #dT& ,dpktSV_dt & ! Reduced Potential Temperature TENDENCY, SISVAT [KX/s] (O) ! #dT& ,dpktAT_dt & ! Reduced Potential Temperature TENDENCY, Atm_AT [KX/s] (O) ! #dT& ,dqv_AT_dt & ! Specific Humidity TENDENCY, Atm_AT [kg/kg/s] (O) ! #dT& ,dqw_AT_dt & ! Cloud Droplets Concentration TENDENCY, Atm_AT [kg/kg/s] (O) ! #dT& ,dqi_AT_dt & ! Cloud Crystals Concentration TENDENCY, Atm_AT [kg/kg/s] (O) ! #dT& ,dqs_AT_dt & ! Snow Particles Concentration TENDENCY, Atm_AT [kg/kg/s] (O) ! #dT& ,dqr_AT_dt & ! Rain Drops Concentration TENDENCY, Atm_AT [kg/kg/s] (O) ! #cw& ,dCw_AT_dt & ! CCN Concentration TENDENCY, Atm_AT [1/s] (O) ! #dT& ,dCi_AT_dt & ! CIN Concentration TENDENCY, Atm_AT [1/s] (O) ! #dT& ,dpktCM_dt & ! Reduced Potential Temperature TENDENCY, CMiPhy [KX/s] (O) ! #dT& ,dqv_CM_dt & ! Specific Humidity TENDENCY, CMiPhy [kg/kg/s] (O) ! #dT& ,dqw_CM_dt & ! Cloud Droplets Concentration TENDENCY, CMiPhy [kg/kg/s] (O) ! #dT& ,dCF_CM_dt & ! Cloud Fraction TENDENCY, CMiPhy [1/s] (O) ! #dT& ,dqi_CM_dt & ! Cloud Crystals Concentration TENDENCY, CMiPhy [kg/kg/s] (O) ! #dT& ,dqs_CM_dt & ! Snow Particles Concentration TENDENCY, CMiPhy [kg/kg/s] (O) ! #dT& ,dqr_CM_dt & ! Rain Drops Concentration TENDENCY, CMiPhy [kg/kg/s] (O) ! #cw& ,dCw_CM_dt & ! CCN Concentration TENDENCY, CMiPhy [1/s] (O) ! #dT& ,dCi_CM_dt & ! CIN Concentration TENDENCY, CMiPhy [1/s] (O) ! #dT& ,dpktCP_dt & ! Reduced Potential Temperature TENDENCY, CVAmnh [KX/s] (O) ! #dT& ,dqv_CP_dt & ! Specific Humidity TENDENCY, CVAmnh [kg/kg/s] (O) ! #dT& ,dqw_CP_dt & ! Cloud Droplets Concentration TENDENCY, CVAmnh [kg/kg/s] (O) ! #dT& ,dqi_CP_dt & ! Cloud Crystals Concentration TENDENCY, CVAmnh [kg/kg/s] (O) ! #dT& ,dpktRT_dt & ! Reduced Potential Temperature TENDENCY, radCEP [KX/s] (O) & ,sst__HOST & ! Ocean FORCING (SST) [K] I ! #IP& ,sif__HOST & ! Ocean FORCING (Sea-Ice Fraction ) [-] I ! #AO& ,s_T__HOST & ! Ocean COUPLING (Surface Temperat.) n=1: Open Ocean [-] I,NEMO ! #AO& ,Alb__HOST & ! Ocean COUPLING (Surface Albedo ) n=2: Sea Ice [-] I,NEMO ! #AO& ,dSdT2HOST & ! Ocean COUPLING ( d(SH Flux) / dT ) [W/m2/K] O ! #AO& ,dLdT2HOST & ! Ocean COUPLING ( d(LH Flux) / dT ) [W/m2/K] O !dead& ,it0EXP,it0RUN & ! Iteration & ,Year_H,Mon__H,Day__H,Hour_H,minu_H,sec__H & ! Time & ,ixq1 ,i0x0 ,mxqq & ! Domain Dimension: x & ,jyq1 ,j0y0 ,myqq & ! Domain Dimension: y & ,mzq ,mzqq & ! Domain Dimension: z & ,mwq & ! Domain Dimension: mosaic & ,kcolq & ! Domain Dimension: x * y & ,kcolw & ! Domain Dimension: x * y * mosaic & ,m_azim & ! Mountain Mask, nb of directions taken into account [-] & ,IOi0SV,IOj0SV,n0pt) ! Indices of OUTPUT Grid Point !------------------------------------------------------------------------------+ ! Sat 29-Jun-2013 MAR | ! subroutine PHY_MAR is the MAR PHYsics Driver | ! interfaces HOST variables | ! and SISVAT variables | ! | ! Applied to: MARthusalem (variables in MAR***.inc files) | ! | ! | ! # OPTIONS: #dT Distinction among Tendencies of MAR Physical Parametr. | ! # ^^^^^^^^ #cw Cloud Condensation Nuclei (CCNw) Microphysics Activation | ! | ! | ! version 3.p.4.1 created by H. Gallee, Tue 12-Mar-2013 | ! Last Modification by H. Gallee, Sat 29-Jun-2013 | ! | !------------------------------------------------------------------------------+ use Mod_Real use Mod_PHY____dat use Mod_PHY____grd use Mod_PHY____kkl use Mod_PHY_CM_ctr use Mod_PHY_S0_ctr use Mod_SISVAT_ctr use Mod_PHY_CM_dat use Mod_PHY_AT_grd use Mod_PHY_CM_grd use Mod_PHY_CP_grd use Mod_PHY_RT_grd use Mod_PHY_S0_grd use Mod_SISVAT_grd use Mod_PHY_DY_kkl use Mod_PHY_AT_kkl use Mod_PHY_CM_kkl use Mod_PHY_CP_kkl use Mod_PHY_RT_kkl use Mod_PHY_S0_kkl use Mod_SISVAT_kkl use Mod_SISVAT_gpt IMPLICIT NONE logical :: FlagSV ! Flag (SISVAT) logical :: FlagSV_Veg ! Flag (SISVAT: Vegetation) logical :: FlagSV_SNo ! Flag (SISVAT: Surface * ) logical :: FlagSV_BSn ! Flag (SISVAT: Blowing * ) logical :: FlagSV_KzT ! Flag (SISVAT: d(KdT/dz)/dz) logical :: FlagSV_SWD ! Flag: T/F : (SISVAT: SW=Down/Abs.) logical :: FlagSV_SBC ! Flag: T/F : (SISVAT: SBC=INP/FIX.) logical :: FlagSV_UBC ! Flag: T/F : (SISVAT: UBC=VonN/Dr.) logical :: FlagAT ! Flag (Turbulent Transfer) character(len=1) :: TypeAT ! Type (Turbulent Transfer) logical :: FlagAT_TKE ! Flag (Turbulent Transfer, TKE-e Model: ON / OFF) logical :: FlagCM ! Flag (Cloud Microphysics) logical :: FlagCM_UpD ! Flag: T/F : (Cloud Microphysics: Update in/out PHY_MAR) logical :: FlagCP ! Flag (Convection Param. ) logical :: FlagRT ! Flag (Radiative Transfer) logical :: FlagS0_SLO ! FLAG (Insolation, Surfac.Slope ) logical :: FlagS0_MtM ! FLAG (Insolation, Surfac.Slope & Mountain Mask) logical :: Flag_O ! Flag (OUTPUT) logical :: FlagVR ! Flag (OUTPUT for VERIFICATION) real :: dt0DYn ! Time Step (DYnamics, the shortest) [s] real :: dt0_SV ! Time Step (SISVAT) [s] real :: dt0_AT ! Time Step (Atmo Turb.) [s] real :: dt0_CM ! Time Step (Cloud Mic.) [s] real :: dt0_CP ! Time Step (Convection) [s] real :: dt0_RT ! Time Step (Radiat.Tr.) [s] real :: dx ! Grid Size [m] real :: DD_AxX ! x-Axis Direction [degree] real, dimension(mzqq) :: s_HOST ! Vertical Coordinate [-] real , dimension(kcolq) :: sh___HOST ! Topography [m] real(kind=real8), dimension(kcolq) :: sh_a_HOST ! Topography Anomaly [m] real(kind=real8), dimension(kcolq) :: slopxHOST ! Slope, x-direction [-] real(kind=real8), dimension(kcolq) :: slopyHOST ! Slope, y-direction [-] real(kind=real8), dimension(kcolq) :: slopeHOST ! Slope [-] real(kind=real8), dimension(kcolq,m_azim) :: MMaskHOST ! Mountain Mask [-] real, dimension(kcolq) :: lonh_HOST ! Longitude [hour] real, dimension(kcolq) :: latr_HOST ! Latitude [radian] real :: ptop_HOST ! Pressure Model Top [kPa] real, dimension(kcolq,mzqq) :: pkta_HOST ! Reduced Potential Temperature [KX/s] real, dimension(kcolq) :: psa__HOST ! Pressure Thickness [kPa] real, dimension(kcolq,mzqq) :: gZa__HOST ! Geopotential Height [m2/s2] real, dimension(kcolq,mzqq) :: gZam_HOST ! Geopotential Height, mid-level [m2/s2] real, dimension(kcolq,mzq) :: Ua___HOST ! Wind Speed, x-direction [m/s] real, dimension(kcolq,mzq) :: Va___HOST ! Wind Speed, y-direction [m/s] real, dimension(kcolq,mzq) ,INTENT(IN) :: Wa___HOST ! Wind Speed, z-direction [m/s] real, dimension(kcolq,mzqq) :: qv___HOST ! Specific Humidity [kg/kg] real, dimension(kcolq,mzq) :: qw___HOST ! Cloud Droplets Concentration [kg/kg] real, dimension(kcolq,mzq) :: CCN__HOST ! CCN Concentration [-/kg] real, dimension(kcolq,mzq) :: qi___HOST ! Cloud Crystals Concentration [kg/kg] real, dimension(kcolq,mzq) :: CIN__HOST ! CIN Concentration [-/kg] real, dimension(kcolq,mzq) :: CF___HOST ! Cloud Fraction [-/kg] real, dimension(kcolq,mzq) :: qs___HOST ! Snow Particles Concentration [kg/kg] real, dimension(kcolq,mzq) :: qr___HOST ! Rain Drops Concentration [kg/kg] real, dimension(kcolq,mzq) :: TKE__HOST ! Turbulent Kinetic Energy [m2/s2] real, dimension(kcolq,mzq) :: eps__HOST ! Turbulent Kinetic Energy Dissipation [m2/s3] real, dimension(kcolq,mzq) :: dpkt___dt ! Reduced Potential Temperature TENDENCY, ALL Contribut.[KX/s] real, dimension(kcolq,mzq) :: dua____dt ! Wind Speed (x-direc.) TENDENCY, ALL Contribut.[m/s2] real, dimension(kcolq,mzq) :: dva____dt ! Wind Speed (y-direc.) TENDENCY, ALL Contribut.[m/s2] real, dimension(kcolq,mzq) :: dqv____dt ! Specific Humidity TENDENCY, ALL Contr. [kg/kg/s] real, dimension(kcolq,mzq) :: dqw____dt ! Cloud Droplets Concentration TENDENCY, ALL Contr. [kg/kg/s] ! #cw real, dimension(kcolq,mzq) :: dCw____dt ! CCN Concentration TENDENCY, ALL Contr. [1/kg/s] real, dimension(kcolq,mzq) :: dqi____dt ! Cloud Crystals Concentration TENDENCY, ALL Contr. [kg/kg/s] real, dimension(kcolq,mzq) :: dCi____dt ! CIN Concentration TENDENCY, ALL Contr. [1/kg/s] real, dimension(kcolq,mzq) :: dCF____dt ! Cloud Fraction TENDENCY, ALL Contr. [kg/kg/s] real, dimension(kcolq,mzq) :: dqs____dt ! Snow Particles Concentration TENDENCY, ALL Contr. [kg/kg/s] real, dimension(kcolq,mzq) :: dqr____dt ! Rain Drops Concentration TENDENCY, ALL Contr. [kg/kg/s] real, dimension(kcolq,mzq) :: dpktSV_dt ! Reduced Potential Temperature Tendency, SISVAT [KX/s] real, dimension(kcolq,mzq) :: dpktAT_dt ! Reduced Potential Temperature Tendency, Atm_AT [KX/s] real, dimension(kcolq,mzq) :: dqv_AT_dt ! Specific Humidity TENDENCY, Atm_AT [kg/kg/s] real, dimension(kcolq,mzq) :: dqw_AT_dt ! Cloud Droplets Concentration TENDENCY, Atm_AT [kg/kg/s] ! #cw real, dimension(kcolq,mzq) :: dCw_AT_dt ! CCN Concentration TENDENCY, Atm_AT [1/s] real, dimension(kcolq,mzq) :: dqi_AT_dt ! Cloud Crystals Concentration TENDENCY, Atm_AT [kg/kg/s] real, dimension(kcolq,mzq) :: dCi_AT_dt ! CIN Concentration TENDENCY, Atm_AT [1/s] real, dimension(kcolq,mzq) :: dqs_AT_dt ! Snow Particles Concentration TENDENCY, Atm_AT [kg/kg/s] real, dimension(kcolq,mzq) :: dqr_AT_dt ! Rain Drops Concentration TENDENCY, Atm_AT [kg/kg/s] real, dimension(kcolq,mzq) :: dpktCM_dt ! Reduced Potential Temperature Tendency, CMiPhy [KX/s] real, dimension(kcolq,mzq) :: dqv_CM_dt ! Specific Humidity TENDENCY, CMiPhy [kg/kg/s] real, dimension(kcolq,mzq) :: dqw_CM_dt ! Cloud Droplets Concentration TENDENCY, CMiPhy [kg/kg/s] ! #cw real, dimension(kcolq,mzq) :: dCw_CM_dt ! CCN Concentration TENDENCY, CMiPhy [1/s] real, dimension(kcolq,mzq) :: dqi_CM_dt ! Cloud Crystals Concentration TENDENCY, CMiPhy [kg/kg/s] real, dimension(kcolq,mzq) :: dCi_CM_dt ! CIN Concentration TENDENCY, CMiPhy [1/s] real, dimension(kcolq,mzq) :: dCF_CM_dt ! Cloud Fraction TENDENCY, CMiPhy [1/s] real, dimension(kcolq,mzq) :: dqs_CM_dt ! Snow Particles Concentration TENDENCY, CMiPhy [kg/kg/s] real, dimension(kcolq,mzq) :: dqr_CM_dt ! Rain Drops Concentration TENDENCY, CMiPhy [kg/kg/s] real, dimension(kcolq,mzq) :: dpktCP_dt ! Reduced Potential Temperature TENDENCY, CVAmnh [KX/s] real, dimension(kcolq,mzq) :: dqv_CP_dt ! Specific Humidity TENDENCY, CVAmnh [kg/kg/s] real, dimension(kcolq,mzq) :: dqw_CP_dt ! Cloud Droplets Concentration TENDENCY, CVAmnh [kg/kg/s] real, dimension(kcolq,mzq) :: dqi_CP_dt ! Cloud Crystals Concentration TENDENCY, CVAmnh [kg/kg/s] real, dimension(kcolq,mzq) :: dpktRT_dt ! Reduced Potential Temperature TENDENCY, radCEP [KX/s] !dead integer :: it0EXP ! !dead integer :: it0RUN ! integer :: Year_H ! Time [year] integer :: Mon__H ! Time [month] integer :: Day__H ! Time [Day] integer :: Hour_H ! Time [hour] integer :: minu_H ! Time [minute] integer :: sec__H ! Time [s] integer :: ixq1,i0x0,mxqq ! Domain Dimension: x [-] integer :: jyq1,j0y0,myqq ! Domain Dimension: y [-] integer :: mzq ! Domain Dimension: z [-] integer :: mzqq ! Domain Dimension: z [-] integer :: mwq ! Domain Dimension: mosaic [-] integer :: kcolq ! Domain Dimension: x * y [-] integer :: kcolw ! Domain Dimension: x * y * mosaic [-] integer :: m_azim ! Mountain Mask, nb of directions taken into account [-] integer, dimension(n0pt) :: IOi0SV ! integer, dimension(n0pt) :: IOj0SV ! integer :: n0pt ! real, dimension(kcolq) :: sst__HOST ! Ocean FORCING (SST) [K] ! #IP real, dimension(kcolq) :: sif__HOST ! Ocean FORCING (Sea-Ice Fraction ) [-] ! #AO real, dimension(ixq1:mxqq,jyq1:myqq,mwq) :: s_T__HOST ! A - O COUPLING n=1: Open Ocean [K] ! #AO real, dimension(ixq1:mxqq,jyq1:myqq,mwq) :: Alb__HOST ! A - O COUPLING (Surface Albedo ) n=2: Sea Ice [-] ! #AO real, dimension(ixq1:mxqq,jyq1:myqq,mwq) :: dSdT2HOST ! A - O COUPLING ( d(SH Flux) / dT ) [W/m2/K] ! #AO real, dimension(ixq1:mxqq,jyq1:myqq,mwq) :: dLdT2HOST ! A - O COUPLING ( d(SH Flux) / dT ) [W/m2/K] ! #TC integer, parameter :: ntrac = 28 ! ! #TC real, dimension(ixq1:mxqq,jyq1:myqq,mzq,ntrac) :: qxTC ! Aerosols: Atmospheric Contentration ! #TC real, dimension(ixq1:mxqq,jyq1:myqq ,ntrac) :: qsTC ! Aerosols: Near Surface Contentration ! #TC real, dimension(ixq1:mxqq,jyq1:myqq ,ntrac) :: uqTC ! Aerosols: Surf.Flux ! ---------------------------------------------------------------------------------! ! LOCAL VARIABLES ! =============== real(kind=real8), dimension(kcolq,mzq) :: Wind_HOST ! Wind Speed, Horizontal [m/s] real(kind=real8) :: dTdz = 0.0065 ! -d(T) / dz Lapse Rate [K/m] real(kind=real8) :: dTimAT ! d(Time) between 2 calls of Atmos.Turbul. [s] integer :: i ,j ,ikl ,ikp ! integer :: k ,mn ! integer :: n ,ipt ,iwr ,kk ! !dead it_RUN = it0RUN !dead it_EXP = it0EXP ! INITIALIZATION ! ============== ! Initialization of local Variables (used each Time Step) ! ------------------------------------------------------- DO k = 1,mzq DO ikl=1,kcolq Wind_HOST(ikl,k) = sqrt(Ua___HOST(ikl,k)*Ua___HOST(ikl,k)+Va___HOST(ikl,k)*Va___HOST(ikl,k)) ENDDO ENDDO ! Initialization of the run ! ------------------------- ! Martin Control PRINT*, 'Dans PHY_MAR:' PRINT*, 'it_RUN=',it_RUN ! Martin Control IF (it_RUN.LE.1) THEN ! Initialization of Mod_SISVAT_grd ! -------------------------------- jt__SV = max(1,int(dt0_SV /dt0DYn)) dt__SV = real(jt__SV)*dt0DYn IF (dt__SV .NE. dt0_SV) write(6,61) dt__SV ,dt0_SV 61 format ('dt__SV =',f9.3,' differs from dt0_SV =',f9.3) ! Initialization of Mod_PHY_AT_grd ! -------------------------------- jt__AT = max(1,int(dt0_AT /dt0DYn)) dt__AT = real(jt__AT)*dt0DYn IF (dt__AT .NE. dt0_AT) write(6,62) dt__AT ,dt0_AT 62 format ('dt__AT =',f9.3,' differs from dt0_AT =',f9.3) ! Initialization of Mod_PHY_CM_grd ! -------------------------------- jt__CM = max(1,int(dt0_CM /dt0DYn)) dt__CM = real(jt__CM)*dt0DYn IF (dt__CM .NE. dt0_CM) write(6,63) dt__CM ,dt0_CM 63 format ('dt__CM =',f9.3,' differs from dt0_CM =',f9.3) ! Initialization of Mod_PHY_CP_grd ! -------------------------------- jt__CP = max(1,int(dt0_CP /dt0DYn)) dt__CP = real(jt__CP)*dt0DYn IF (dt__CP .NE. dt0_CP) write(6,64) dt__CP ,dt0_CP 64 format ('dt__CP =',f9.3,' differs from dt0_CP =',f9.3) ! Initialization of Mod_PHY_RT_grd ! -------------------------------- jt__RT = max(1,int(dt0_RT /dt0DYn)) dt__RT = real(jt__RT)*dt0DYn IF (dt__RT .NE. dt0_RT) write(6,65) dt__RT ,dt0_RT 65 format ('dt__RT =',f9.3,' differs from dt0_RT =',f9.3) ! Initialization ! -------------- ! Initialization of 1-D Axes Variables: Vertical Axis (Atmosphere) ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ pt__DY = ptop_HOST DO k=1,mzpp sigma(k) = s_HOST(k) ENDDO ! Martin control !PRINT*,'s_HOST=',s_HOST ! Martin control DO k=1,mzp k1m(k) = max(k-1, 1) k1p(k) = min(k+1,mzp) k2m(k) = max(k-2, 1) dsigma(k) = sigma(k+1) - sigma(k) sigmi(k+1) = (sigma(k+1) + sigma(k)) * 0.5 END DO sigmi(1) = 0.0 sigmi(mzpp)= 1.0 DO k=1,mzp dsigmi(k) = sigmi(k+1) - sigmi(k) ! Guess of sigma-levels Height ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~ hsigma(k) =-(288./.0065)*(sigma(k) ** (287.*.0065/9.81)-1.) END DO write(6,501) (sigma(k),k=1,mzpp) 501 format(/,' sigma: ',10f8.5 & & ,5(/,' ',10f8.5)) write(6,502)(hsigma(k),k=1,mzp) 502 format(/,' hsigma: ',10f8.1 & & ,5(/,' ',10f8.1)) ! Initialization of Mod_PHY____dat & Mod_PHY____kkl ! ------------------------------------------------- ! Topography ! ~~~~~~~~~~ sh_MAX = 0. DO ikl = 1,kcolp sh__AP(ikl) = sh___HOST(ikl) sha_AP(ikl) = sh_a_HOST(ikl) ! Surface Slope ! ~~~~~~~~~~~~~ sloxAP(ikl) = slopxHOST(ikl) sloyAP(ikl) = slopyHOST(ikl) slopAP(ikl) = slopeHOST(ikl) sh_MAX = max(sh_MAX,sh__AP (ikl)) END DO dzaMIN = hsigma(mzp) *(hsigma(1) -sh_MAX) /hsigma(1) DO ikl = 1,kcolp ! Geographic Coordinates ! ~~~~~~~~~~~~~~~~~~~~~~ ! Martin rearrangement pour que RADACA ne plante plus: ! lon__r(ikl) = lonh_HOST(ikl) * 2.0 * piNmbr / 24.0 IF ((lonh_HOST(ikl) ) .LT. 0) THEN lon__r(ikl) = 360 + (lonh_HOST(ikl) * 2.0 * piNmbr / 24.0) ELSE lon__r(ikl) = (lonh_HOST(ikl) * 2.0 * piNmbr / 24.0) ENDIF lon__h(ikl) = lonh_HOST(ikl) lat__r(ikl) = latr_HOST(ikl) sinLat(ikl) = sin(lat__r(ikl)) cosLat(ikl) = cos(lat__r(ikl)) ENDDO ! -----------------------------------------------------------------------------! ! Initialization of Atm_DY (Counterpart of dynamical variables in PHY_MAR) ! ------------------------- ! Martin control !PRINT*,'Avant PHY_Atm_DY_INI' !PRINT*,'size(psa_DY)=',size(psa_DY) ! Martin control ! ************** CALL PHY_Atm_DY_INI ! ************** ! Initialization of Atm_DY: needs plausible Atmospheric Conditions ! ~~~~~~~~~~~~~~~~~~~~~~~~~ (here idealized for Temperature Vertical Gradient) ! Martin control !PRINT*,'Apres PHY_Atm_DY_INI' !PRINT*,'size(psa_DY)=',size(psa_DY) !PRINT*,'Dans PHY_MAR, calcul de Ta__DY:' !PRINT*,'mzpp=',mzpp !PRINT*,'pt__DY=',pt__DY !PRINT*,'Dtdz=',dTdz !PRINT*,'RCp=',RCp !PRINT*,'minval(pkta(:,mzpp))=',minval(pkta_HOST(:,mzpp)) !PRINT*,'minval(psa__HOST(:))=',minval(psa__HOST(:)) !PRINT*,'minval(Z___DY(:,:))=',minval(Z___DY(:,:)) !PRINT*,'minval(Ta__DY(:,mzpp))=',minval(Ta__DY(:,mzpp)) ! Martin control DO ikl = 1,kcolp i = ii__AP (ikl) j = jj__AP (ikl) psa_DY (ikl ) = psa__HOST(ikl) Ta__DY (ikl,mzpp) = pkta_HOST(ikl,mzpp)*(psa_DY(ikl)+pt__DY)**RCp DO k = mzp,1,-1 Z___DY (ikl,k ) = & & Ta__DY(ikl,mzpp) & & * (1.0 - ((psa_DY(ikl)*sigma (k)+pt__DY) & & /(psa_DY(ikl) +pt__DY)) & & **(R_DAir * dTdz /Grav_F)) / dTdz Ta__DY (ikl,k) = & & Ta__DY(ikl,mzpp) -Z___DY(ikl,k) * dTdz qv__DY (ikl,k) = 0.001 WindDY (ikl,k) = Wind_HOST(ikl,k) ua__DY (ikl,k) = Ua___HOST(ikl,k) va__DY (ikl,k) = va___HOST(ikl,k) wa__DY (ikl,k) = Wa___HOST(ikl,k) ENDDO ENDDO ! Martin Control !PRINT*,'Avant PHY_Atm_S0_INI' !PRINT*,'minval(Ta__DY(:,:))=',minval(Ta__DY(:,:)) ! -----------------------------------------------------------------------------! ! Initialization of Atm_S0 (Insolation and cos of Sun Zenithal Distance) ! ------------------------- ! ************** CALL PHY_Atm_S0_INI ! ************** ! Initialization of Mod_PHY_S0_ctr and Mod_PHY_S0_kkl ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ FaceS0 = FlagS0_SLO MMskS0 = FlagS0_MtM IF (FlagS0_SLO .AND. FlagS0_MtM) THEN DO k = 1,m_azim DO ikl = 1,kcolp cszkS0(ikl,k) = MMaskHOST(ikl,k) ENDDO ENDDO ENDIF ! -----------------------------------------------------------------------------! ! Initialization of SISVAT ! ------------------------- ! Initialization of Mod_SISVAT_ctr (SISVAT Switches ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ & Time/Space control Variables) VegMod = FlagSV_Veg SnoMod = FlagSV_SNo BloMod = FlagSV_BSn InpSWD = FlagSV_SWD InpSBC = FlagSV_SBC SVaKzT = FlagSV_KzT SVaUBC = FlagSV_UBC ! Initialization of Mod_SISVAT_kkl (from INPUT from HOST Model) ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ DO ikp = 1,kcolp i = ii__AP(ikp) j = jj__AP(ikp) DO mn = 1,mwp DO k = 1,mzp kk = mzpp - k WindSV(ikp,mn,k) = Wind_HOST(ikp,k) pkt0SV(ikp,mn,kk)= pkta_HOST(ikp,k) END DO Ua__SV(ikp,mn) = Ua___HOST(ikp,mzp) Va__SV(ikp,mn) = Va___HOST(ikp,mzp) END DO END DO ! Initialization of SISVAT Variables ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ ! ************** CALL PHY_SISVAT_INI ! ************** ! Initialization of Mod_SISVAT_kkl (SISVAT OUTPUT Grid Points) ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ iwr = 0 DO ipt = 1,NbPts IF (IOi0SV(ipt).EQ.0) THEN IOi_SV(ipt)=i_x0 ELSE IOi_SV(ipt)=IOi0SV(ipt) END IF IF (IOj0SV(ipt).EQ.0) THEN IOj_SV(ipt)=j_y0 ELSE IOj_SV(ipt)=IOj0SV(ipt) END IF write(6,*) 'ipt , IOi_SV, IOj_SV = ' & & ,ipt , IOi_SV(ipt), IOj_SV(ipt) DO n = 1,mwp iwr = 1+iwr IF (iwr.LE.nbwri) THEN no__SV(iwr) = 0 i___SV(iwr) = IOi_SV(ipt) j___SV(iwr) = IOj_SV(ipt) n___SV(iwr) = n write(6,*) 'n , i___SV, j___SV, n___SV, iwr = ' & & ,n , i___SV(iwr), j___SV(iwr), n___SV(iwr), iwr END IF END DO END DO ! -----------------------------------------------------------------------------! ! Initialization of Atm_RT (Radiative Transfert through the Atmosphere) ! ------------------------- ! ************** CALL PHY_Atm_RT_INI ! ************** ! -----------------------------------------------------------------------------! ! Initialization of Atm_AT (Turbulent Transfert through the Atmosphere) ! ------------------------- ! ************** CALL PHY_Atm_AT_INI(FlagAT_TKE,TypeAT) ! ************** ! -----------------------------------------------------------------------------! ! Initialization of Atm_CP (Convectiv Transfert through the Atmosphere) ! ------------------------- ! ************** CALL PHY_Atm_CP_INI(mzp,kcolp) ! ************** ! -----------------------------------------------------------------------------! ! Initialization of CMiPhy (Cloud Microphysical Scheme) ! ------------------------- ! Initialization of Mod_PHY_CM_ctr (CMiPhy Switches ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ & Time/Space control Variables) CM_UpD = FlagCM_UpD ! ************** CALL PHY_Atm_CM_INI ! ************** END IF ! Martin CONTROL !PRINT*, 'Impressions control' !call iophys_ecrit('TA__DY_surf',1,'surface temperature','K',Ta__DY(:,61)) !call iophys_ecrit('TA__DY_air',60,'air temperature','K',Ta__DY(:,1:60)) !PRINT*,'TA__DY(:,61)=',TA__DY(kcolq/2,61) ! Interface: From HOST Model Variables to MARp Physics Variables ! ============================================================== ! Time ! ---- YearTU = Year_H Mon_TU = Mon__H Day_TU = Day__H HourTU = Hour_H minuTU = minu_H sec_TU = sec__H TimeTU = (float(351)+(float(YearTU) -float(1902)) *float(365)&! Nb Days before YearTU & +(float(YearTU) -float(1901)) /float( 4)&! Nb Leap Years & + float(njYear(Mon_TU)) &! Nb Days before Mon_TU & + float(njLeap(Mon_TU)) &! (including Leap Day) & *max(zer0,un_1-mod(float(YearTU),float(4))) &! & + float(Day_TU)-float(1) ) *float( 24)&! & +float(HourTU) &! & + (float(minuTU) *float(60) +float(sec_TU))/3600. ! ! -----------------------------------------------------------------------------! ! Assignation of Mod_PHY_AT_grd ! --------------------------------- IF (it_RUN .EQ. 1) THEN TimeAT = TimeTU-dt0_AT/3600. ! Initialisation à la première itération END IF IF (FlagAT .AND. mod(it_RUN-1,jt__AT).EQ.0) THEN dTimAT = (TimeTU-TimeAT) * 3600. TimeAT = TimeTU END IF ! Martin CONTROL PRINT*,'CONTROL PHY_MAR temps' PRINT*,' Year_H =', Year_H PRINT*,' Mon__H =', Mon__H PRINT*,' Day__H =', Day__H PRINT*,' Hour_H =', Hour_H PRINT*,' minu_H =', minu_H PRINT*,' sec__H =', sec__H PRINT*,'jt__AT=',jt__AT PRINT*,'TimeTU=',TimeTU PRINT*,'TimeAT=',TimeAT PRINT*,'dTimAT=',dTimAT ! Martin CONTROL ! -----------------------------------------------------------------------------! ! Assignation of Mod_PHY_DY_kkl ! --------------------------------- DO ikl=1,kcolp i = ii__AP(ikl) j = jj__AP(ikl) k = mzpp ExnrDY (ikl,k) = exp(RCp *log(psa__HOST(ikl)*sigma(k)+pt__DY)) pkt_DY (ikl,k) = pkta_HOST(ikl,k) Ta__DY (ikl,k) = pkta_HOST(ikl,k) * ExnrDY(ikl,k) ! CAUTION: Tas_SV_xy is not allowed to be changed by data coming from outside this routine Z___DY (ikl,k) = gZa__HOST(ikl,k) *Grav_I ZmidDY (ikl,k) = gZam_HOST(ikl,k) *Grav_I qv__DY (ikl,k) = qv___HOST(ikl,k) DO k = 1,mzp ExnrDY (ikl,k) = exp(RCp *log(psa__HOST(ikl)*sigma(k )+pt__DY)) pkt_DY (ikl,k) = pkta_HOST(ikl,k) Ta__DY (ikl,k) = pkta_HOST(ikl,k) * ExnrDY(ikl,k) roa_DY (ikl,k) = (psa__HOST(ikl)*sigma(k )+pt__DY) & & /(Ta__DY (ikl,k) *R_DAir) roamDY (ikl,k) = (psa__HOST(ikl)*sigmi(k+1)+pt__DY) & & /(Ta__DY (ikl,k) *R_DAir) Z___DY (ikl,k) = gZa__HOST(ikl,k) *Grav_I ZmidDY (ikl,k) = gZam_HOST(ikl,k) *Grav_I qv__DY (ikl,k) = qv___HOST(ikl,k) ! -----------------------------------------------------------------------------! ! Assignation of Mod_PHY_AT_kkl ! --------------------------------- IF (FlagAT.AND.it_EXP.GT.1.AND.mod(it_RUN-1,jt__AT).EQ.0) THEN TKE_AT (ikl,k) = TKE__HOST(ikl,k) eps_AT (ikl,k) = eps__HOST(ikl,k) TrT_AT (ikl,k) = (TKE_AT (ikl,k) - TrT_AT (ikl,k)) & & / dTimAT END IF ! -----------------------------------------------------------------------------! ! Assignation of Mod_PHY_CM_kkl ! --------------------------------- IF (FlagCM.AND.it_EXP.GT.1.AND.mod(it_RUN-1,jt__CM).EQ.0) THEN ! IF (qw___HOST(ikl,k).LT.qh_MIN) THEN ! qv__DY(ikl,k) = qv__DY(ikl,k) + qw__CM(ikl,k) ! qw__CM(ikl,k) = 0. ! #cw CCNwCM(ikl,k) = 0. ! ELSE qw__CM(ikl,k) = qw___HOST(ikl,k) ! #cw CCNwCM(ikl,k) = CCN__HOST(ikl,k) ! END IF ! IF (qi___HOST(ikl,k).LT.qh_MIN) THEN ! qv__DY(ikl,k) = qv__DY(ikl,k) + qi__CM(ikl,k) ! qi__CM(ikl,k) = 0. ! CCNiCM(ikl,k) = 0. ! ELSE qi__CM(ikl,k) = qi___HOST(ikl,k) CCNiCM(ikl,k) = CIN__HOST(ikl,k) ! END IF ! Gilles: CF___HOST non sauve & CFraCM reinitialise ici ! CFraCM(ikl,k) = CF___HOST(ikl,k) ! IF (qw__CM(ikl,k).LT.qh_MIN .AND. & ! & qi__CM(ikl,k).LT.qh_MIN) THEN ! CFraCM(ikl,k) = 0. ! ELSE ! CFraCM(ikl,k) = max(CFrMIN,CF___HOST(ikl,k)) ! END IF qs__CM(ikl,k) = qs___HOST(ikl,k) qr__CM(ikl,k) = qr___HOST(ikl,k) END IF ENDDO ! -----------------------------------------------------------------------------! ! Assignation of Mod_SISVAT_gpt (A-O FORCING OR COUPLING) ! --------------------------------- sst_SB (ikl) = sst__HOST(ikl) ! #IP sif_SB (ikl) = sif__HOST(ikl) ! #AO DO k = 1,mwp ! #AO s_T_AO_xyn(i,j,k) = s_T__HOST(ikl,k) ! #AO Alb_AO_xyn(i,j,k) = Alb__HOST(ikl,k) ! #AO ENDDO ENDDO ! -----------------------------------------------------------------------------! ! Assignation of Mod_PHY_DY_kkl ! --------------------------------- DO ikl = 1,kcolp i = ii__AP(ikl) j = jj__AP(ikl) psa_DY(ikl) = psa__HOST(ikl) DO k = 1,mzp WindDY(ikl,k) = Wind_HOST(ikl,k) ua__DY(ikl,k) = Ua___HOST(ikl,k) va__DY(ikl,k) = va___HOST(ikl,k) wa__DY(ikl,k) = Wa___HOST(ikl,k) + sqrt(2.*max(eps6,TKE_AT(ikl,k))/3.) END DO END DO ! ************** CALL PHY_Atm_DY_RUN ! Assignation of MAR Dyn. Variables ! ************** IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_Atm_DY_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF ! -----------------------------------------------------------------------------! ! Saturation Specific Humidity ! ---------------------------- IF (FlagCM .OR. &! *************** & FlagSV) CALL PHY_Atm_CM_QSat ! *************** ! -----------------------------------------------------------------------------! ! Execution of Atm_S0 (Insolation and cos of Sun Zenithal Distance) ! ------------------------- ! ************** CALL PHY_Atm_S0_RUN ! ************** IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_Atm_S0_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF ! -----------------------------------------------------------------------------! ! Execution of Atm_RT (Radiative Transfer through the Atmosphere) ! ------------------------- IF (FlagRT .AND. mod(it_RUN-1,jt__RT).EQ.0) THEN ! ************** CALL PHY_Atm_RT_RUN(kcolp,ikl0) ! ************** IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_Atm_RT_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF END IF ! -----------------------------------------------------------------------------! ! Execution of SISVAT (Soil-Ice-Snow-Vegetation-Atmosphere-Transfer Scheme) ! ------------------------- IF (FlagSV) THEN ! Assignation of Mod_SISVAT_kkl (from INPUT from HOST Model) ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ DO ikp = 1,kcolp DO mn = 1,mwp pkPaSV(ikp,mn) = psa__HOST(ikp) +pt__DY ExnrSV(ikp,mn) = exp(RCp *log(psa__HOST(ikp)*sigma(mzp)+pt__DY)) DO k = 1,mzp kk = mzpp - k WindSV(ikp,mn,k) = Wind_HOST(ikp,k) pkt0SV(ikp,mn,kk)= pkta_HOST(ikp,k) qv__SV(ikp,mn,kk)= qv___HOST(ikp,k) zza_SV(ikp,mn,kk)= (gZa__HOST(ikp,k) & ! & -gZa__HOST(ikp,mzpp)) *Grav_I ! roa_SV(ikp,mn,kk)= roa_DY (ikp,k) * 1.e3 ! [kg/m3] END DO Ua__SV(ikp,mn) = Ua___HOST(ikp,mzp) Va__SV(ikp,mn) = Va___HOST(ikp,mzp) TaT_SV(ikp,mn) = pkta_HOST(ikp,mzp) * ExnrSV(ikp,mn) END DO END DO ! ************** CALL PHY_SISVAT_RUN( & ! ************** ! -----------------------------------------------------------------------------! ! #TC& qxTC,uqTC ,qsTC , & ! Aerosols: Atm.Conc., Surf.Flux ! -----------------------------------------------------------------------------! & ) IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_SISVAT_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF END IF ! -----------------------------------------------------------------------------! ! Execution of Atm_AT (Atmospheric Turbulence Contribution) ! ------------------------- IF (FlagAT .AND. mod(it_RUN-1,jt__AT).EQ.0) THEN ! ************** CALL PHY_Atm_AT_RUN(FlagSV_KzT,FlagCM) ! ************** IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_Atm_AT_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF END IF ! -----------------------------------------------------------------------------! ! Execution of Atm_CP (Convection Parameterisation - Mass Flux Scheme) ! ------------------------- IF (FlagCP .AND. mod(it_RUN-1,jt__CP).EQ.0) THEN ! ************** CALL PHY_Atm_CP_RUN(mzp,kcolp) ! CALL PHY_Atm_CP_RUN(mxp,kcolp) ! ancien bug ! ************** IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_Atm_CP_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF END IF ! -----------------------------------------------------------------------------! ! Execution of Atm_CM (Cloud Microphysics) ! ------------------------- IF (FlagCM .AND. mod(it_RUN-1,jt__CM).EQ.0) THEN ! ************** CALL PHY_Atm_CM_RUN ! ************** IF(FlagVR) THEN ! ************** CALL PHY________OUT('After PHY_Atm_CM_RUN ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF END IF ! Assignation of the Tendencies to transfer outside the physical Parameterizations Package ! ======================================================================================== DO ikl=1,kcolp i = ii__AP(ikl) j = jj__AP(ikl) ! -----------------------------------------------------------------------------! ! Reinitialization of the Tendencies ! ---------------------------------- DO k= 1,mzp dpkt___dt(ikl,k) = 0.0 ! dua____dt(ikl,k) = 0.0 ! dva____dt(ikl,k) = 0.0 ! dqv____dt(ikl,k) = 0.0 ! dqw____dt(ikl,k) = 0.0 ! dCF____dt(ikl,k) = 0.0 ! dqi____dt(ikl,k) = 0.0 ! dCi____dt(ikl,k) = 0.0 ! dqs____dt(ikl,k) = 0.0 ! dqr____dt(ikl,k) = 0.0 ! ! -----------------------------------------------------------------------------! ! Tendencies from SISVAT ! ---------------------- IF (FlagSV .AND. mod(it_RUN-1,jt__SV).EQ.0) THEN! dpktSV_dt(ikl,k) = dpktSV_gpt(ikl,k) ! Reduced Potential Temperature TENDENCY, SISVAT [KX/s] END IF ! Update of the tendencies ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ IF (FlagSV) THEN! dpkt___dt(ikl,k) = dpkt___dt(ikl,k) + dpktSV_gpt(ikl,k) ! END IF ! -----------------------------------------------------------------------------! ! Tendencies from Atm_AT ! ---------------------- IF (FlagAT .AND. mod(it_RUN-1,jt__AT).EQ.0) THEN! dua____dt(ikl,k) = dua_AT(ikl,k) ! Wind Speed (x-direc.) TENDENCY, ALL Contribut.[m/s2] dva____dt(ikl,k) = dva_AT(ikl,k) ! Wind Speed (y-direc.) TENDENCY, ALL Contribut.[m/s2] dpktAT_dt(ikl,k) = dpktAT(ikl,k) ! Reduced Potential Temperature TENDENCY, Atm_AT [KX/s] dqv_AT_dt(ikl,k) = dqv_AT(ikl,k) ! Specific Humidity TENDENCY, Atm_AT [kg/kg/s] dqw_AT_dt(ikl,k) = dqw_AT(ikl,k) ! Cloud Droplets Concentration TENDENCY, Atm_AT [kg/kg/s] dqi_AT_dt(ikl,k) = dqi_AT(ikl,k) ! Cloud Crystals Concentration TENDENCY, Atm_AT [kg/kg/s] dqs_AT_dt(ikl,k) = dqs_AT(ikl,k) ! Snow Particles Concentration TENDENCY, Atm_AT [kg/kg/s] dqr_AT_dt(ikl,k) = dqr_AT(ikl,k) ! Rain Drops Concentration TENDENCY, Atm_AT [kg/kg/s] ! #cw dCw_AT_dt(ikl,k) = dCW_AT(ikl,k) ! CCN Concentration TENDENCY, Atm_AT [1/s] dCi_AT_dt(ikl,k) = dCi_AT(ikl,k) ! CIN Concentration TENDENCY, Atm_AT [1/s] ! NO Tendencies on TKE and its dissipation ==> TKE__HOST and eps__HOST are updated ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ TKE__HOST(ikl,k) = TKE_AT(ikl,k) ! eps__HOST(ikl,k) = eps_AT(ikl,k) ! ! Re-Initialization of the TKE Transport Rate ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ TrT_AT (ikl,k) = TKE_AT(ikl,k) ! END IF ! Update of the tendencies ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ IF (FlagAT) THEN! dpkt___dt(ikl,k) = dpkt___dt(ikl,k) + dpktAT(ikl,k) ! dqv____dt(ikl,k) = dqv____dt(ikl,k) + dqv_AT(ikl,k) ! dqw____dt(ikl,k) = dqw____dt(ikl,k) + dqw_AT(ikl,k) ! dqi____dt(ikl,k) = dqi____dt(ikl,k) + dqi_AT(ikl,k) ! dqs____dt(ikl,k) = dqs____dt(ikl,k) + dqs_AT(ikl,k) ! dqr____dt(ikl,k) = dqr____dt(ikl,k) + dqr_AT(ikl,k) ! ! #cw dCw____dt(ikl,k) = dCw____dt(ikl,k) + dCw_AT(ikl,k) ! dCi____dt(ikl,k) = dCi____dt(ikl,k) + dCi_AT(ikl,k) ! END IF ! -----------------------------------------------------------------------------! ! Tendencies from CMiPhy (dqw_CM, dCw_CM, dqi_CM, dCi_CM ! ---------------------- dqs_CM, dqr_CM are consumed in CMiPhy then reset to 0 ! if FlagCM_UpD = .TRUE. ) IF (FlagCM .AND. mod(it_RUN-1,jt__CM).EQ.0) THEN! dpktCM_dt(ikl,k) = dpktCM(ikl,k) ! Reduced Potential Temperature TENDENCY, CMiPhy [KX/s] dqv_CM_dt(ikl,k) = dqv_CM(ikl,k) ! Specific Humidity TENDENCY, CMiPhy [kg/kg/s] dqw_CM_dt(ikl,k) = dqw_CM(ikl,k) ! Cloud Droplets Concentration TENDENCY, CMiPhy [kg/kg/s] dCF_CM_dt(ikl,k) = dCF_CM(ikl,k) ! Cloud Fraction TENDENCY, CMiPhy [kg/kg/s] dqi_CM_dt(ikl,k) = dqi_CM(ikl,k) ! Cloud Crystals Concentration TENDENCY, CMiPhy [kg/kg/s] dqs_CM_dt(ikl,k) = dqs_CM(ikl,k) ! Snow Particles Concentration TENDENCY, CMiPhy [kg/kg/s] dqr_CM_dt(ikl,k) = dqr_CM(ikl,k) ! Rain Drops Concentration TENDENCY, CMiPhy [kg/kg/s] ! #cw dCw_CM_dt(ikl,k) = dCW_CM(ikl,k) ! CCN Concentration TENDENCY, CMiPhy [1/s] dCi_CM_dt(ikl,k) = dCi_CM(ikl,k) ! CIN Concentration TENDENCY, CMiPhy [1/s] END IF ! Update of the tendencies ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ IF (FlagCM) THEN! dpkt___dt(ikl,k) = dpkt___dt(ikl,k) + dpktCM(ikl,k) ! dqv____dt(ikl,k) = dqv____dt(ikl,k) + dqv_CM(ikl,k) ! dqw____dt(ikl,k) = dqw____dt(ikl,k) + dqw_CM(ikl,k) ! dCF____dt(ikl,k) = dCF____dt(ikl,k) + dCF_CM(ikl,k) ! dqi____dt(ikl,k) = dqi____dt(ikl,k) + dqi_CM(ikl,k) ! dqs____dt(ikl,k) = dqs____dt(ikl,k) + dqs_CM(ikl,k) ! dqr____dt(ikl,k) = dqr____dt(ikl,k) + dqr_CM(ikl,k) ! ! #cw dCw____dt(ikl,k) = dCw____dt(ikl,k) + dCw_CM(ikl,k) ! dCi____dt(ikl,k) = dCi____dt(ikl,k) + dCi_CM(ikl,k) ! END IF ! -----------------------------------------------------------------------------! ! Tendencies from CVAmnh ! ---------------------- IF (FlagCP .AND. mod(it_RUN-1,jt__CP).EQ.0) THEN! dpktCP_dt(ikl,k) = dpktCP(ikl,k) ! Reduced Potential Temperature TENDENCY, CVAmnh [KX/s] dqv_CP_dt(ikl,k) = dqv_CP(ikl,k) ! Specific Humidity TENDENCY, CVAmnh [kg/kg/s] dqw_CP_dt(ikl,k) = dqw_CP(ikl,k) ! Cloud Droplets Concentration TENDENCY, CVAmnh [kg/kg/s] dqi_CP_dt(ikl,k) = dqi_CP(ikl,k) ! Cloud Crystals Concentration TENDENCY, CVAmnh [kg/kg/s] END IF ! Update of the tendencies ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ IF (FlagCP) THEN! dpkt___dt(ikl,k) = dpkt___dt(ikl,k) + dpktCP(ikl,k) ! dqv____dt(ikl,k) = dqv____dt(ikl,k) + dqv_CP(ikl,k) ! dqw____dt(ikl,k) = dqw____dt(ikl,k) + dqw_CP(ikl,k) ! dqi____dt(ikl,k) = dqi____dt(ikl,k) + dqi_CP(ikl,k) ! END IF ! -----------------------------------------------------------------------------! ! Tendencies from radCEP ! ---------------------- IF (FlagRT .AND. mod(it_RUN-1,jt__RT).EQ.0) THEN! dpktRT_dt(ikl,k) = dpktRT(ikl,k) ! Reduced Potential Temperature TENDENCY, radCEP [KX/s] END IF ! Update of the tendencies ! ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~ IF (FlagRT) THEN! dpkt___dt(ikl,k) = dpkt___dt(ikl,k) + dpktRT(ikl,k) ! END IF ENDDO ! Assignation of the Variables to keep inside the Physical Parameterizations Package ! ======================================================================================== ! ... NOTHING up to now ! Assignation of the Variables to transfer outside the Physical Parameterizations Package ! ======================================================================================== ! -----------------------------------------------------------------------------! ! Update of pkta_HOST, qv___HOST ! ------------------------------- DO k=1,mzpp pkta_HOST(ikl,k) = pkt_DY(ikl,k) ! Always on k=mzpp, possible from 1 to mzp (with dpkt = 0.) qv___HOST(ikl,k) = qv__DY(ikl,k) ! ENDDO ! -----------------------------------------------------------------------------! ! Update of qw___HOST, CF___HOST, qi___HOST, CIN__HOST, qs___HOST, qr___HOST ! --------------------------------------------------------------------------- IF (FlagCM) THEN DO k=1,mzp qw___HOST(ikl,k) = qw__CM(ikl,k) ! #cw CCN__HOST(ikl,k) = CCNwCM(ikl,k) CF___HOST(ikl,k) = CFraCM(ikl,k) qi___HOST(ikl,k) = qi__CM(ikl,k) CIN__HOST(ikl,k) = CCNiCM(ikl,k) qs___HOST(ikl,k) = qs__CM(ikl,k) qr___HOST(ikl,k) = qr__CM(ikl,k) ENDDO END IF ! -----------------------------------------------------------------------------! ! Update of d(S,LH)/dT (needed in NEMO) ! --------------------- ! #AO DO k=1,mwpp ! #AO dSdT2HOST(ikl,k) = dSdTAO_xyn(i,j,k) ! #AO dLdT2HOST(ikl,k) = dLdTAO_xyn(i,j,k) ! #AO ENDDO ENDDO ! OUTPUT ! ====== ! OUTPUT of Tendencies ! -------------------- IF (FlagVR .OR. & & (FLAG_O .AND. ((minuTU.EQ.0 .AND. sec_TU.EQ.0) .OR. & & it_RUN.EQ.1 ))) THEN ikl = ikl0 i = ii__AP(ikl) j = jj__AP(ikl) ! pkt TENDENCIES ! ~~~~~~~~~~~~~~ write(4,400) 400 format(//,' pkt TENDENCIES',/,' **************'/,1x) write(4,403) Day_TU,Mon_TU,YearTU,HourTU,MinuTU,Sec_TU,it_EXP 403 format(3x,2(i2,'-'),i4,4x,3(i2,'-'),' Simulation Iteration No ',i6,/,1x) write(4,404) write(4,401) 401 format(' | SISVAT | Atm_AT | CMiPhy | CVAmnh | radCEP |') write(4,402) 402 format(' | [K/d] | [K/d] | [K/d] | [K/d] | [K/d] |') write(4,404) 404 format(4('-'),'+',5(13('-'),'+')) DO k=1,mzp write(4,405) k & & , ExnrDY(ikl,k)*dpktSV_gpt(ikl,k)*86400. & & , ExnrDY(ikl,k)*dpktAT (ikl,k)*86400. & & , ExnrDY(ikl,k)*dpktCM (ikl,k)*86400. & & , ExnrDY(ikl,k)*dpktCP (ikl,k)*86400. & & , ExnrDY(ikl,k)*dpktRT (ikl,k)*86400. 405 format(i3,' |',5(f12.6,' |')) IF (mod(k,20).EQ.0) THEN write(4,404) write(4,401) write(4,402) write(4,404) END IF ENDDO write(4,404) ! pkt TENDENCIES ! ~~~~~~~~~~~~~~ write(4,410) 410 format(//,' Qv TENDENCIES',/,' **************'/,1x) write(4,403) Day_TU,Mon_TU,YearTU,HourTU,MinuTU,Sec_TU,it_EXP !403 format(3x,2(i2,'-'),i4,4x,3(i2,'-'),' Simulation Iteration No ',i6,/,1x) write(4,404) write(4,411) 411 format(' | SISVAT | Atm_AT | CMiPhy | CVAmnh | TOTAL |') write(4,412) 412 format(' | [g/kg/min] | [g/kg/min] | [g/kg/min] | [g/kg/min] | [g/kg/min] |') write(4,404) !404 format(4('-'),'+',5(13('-'),'+')) DO k=1,mzp write(4,415) k & & , dqv_AT (ikl,k)*60000. & & , dqv_CM (ikl,k)*60000. & & , dqv_CP (ikl,k)*60000. & & , dqv____dt(ikl,k)*60000. 415 format(i3,' |',12x,' |',4(f12.6,' |')) IF (mod(k,20).EQ.0) THEN write(4,404) write(4,411) write(4,412) write(4,404) END IF ENDDO write(4,404) END IF IF (FLAG_O .AND. ((minuTU.EQ.0 .AND. sec_TU.EQ.0) .OR. & & it_RUN.EQ.1 )) THEN ! ************** CALL PHY________OUT('After PHY_MAR ') ! ************** 12345678901234567890123456789012345678901234567890 ! 1 2 3 4 5 END IF return end