1 | !******************************************************************************* |
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2 | ! PURPOSE: LMD_driver is the WRF mediation layer routine that provides the |
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3 | ! interface to LMD physics packages in the WRF model layer. For those familiar |
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4 | ! with the LMD GCM, the aim of this driver is to do part of the job of the |
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5 | ! calfis.F routine. |
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6 | !******************************************************************************* |
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7 | ! AUTHOR: A. Spiga - January 2007 |
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8 | !******************************************************************************* |
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9 | ! UPDATES: - included all final updates for the paper - March 2008 |
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10 | ! - general cleaning of code and comments - October 2008 |
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11 | ! - additions for idealized cases - January 2009 |
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12 | ! - additions for new soil model in physics - January 2010 |
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13 | ! - unified module_lmd_driver: old, new phys and LES - February 2011 |
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14 | ! - a new paradigm to prepare nested simulations - April 2014 |
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15 | ! - adapted to new interface philosophy & other planets - August 2016 |
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16 | ! - adapated to WRFV4 - JL22 |
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17 | !******************************************************************************* |
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18 | MODULE module_lmd_driver |
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19 | CONTAINS |
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20 | SUBROUTINE lmd_driver(id,max_dom,DT,ITIMESTEP,XLAT,XLONG, & |
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21 | IDS,IDE,JDS,JDE,KDS,KDE,IMS,IME,JMS,JME,KMS,KME, & |
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22 | i_start,i_end,j_start,j_end,kts,kte,num_tiles, & |
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23 | DX,DY, & |
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24 | MSFT,MSFU,MSFV, & |
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25 | GMT,JULYR,JULDAY, & |
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26 | P8W,DZ8W,T8W,Z,HT,MUT,DNW, & |
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27 | U,V,TH,T,P,EXNER,RHO, & |
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28 | P_HYD, P_HYD_W, & |
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29 | PTOP, & |
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30 | RADT, & |
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31 | TSK,PSFC, & |
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32 | RTHPLATEN,RUPLATEN,RVPLATEN, & |
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33 | num_3d_s,SCALAR, & |
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34 | num_3d_m,moist, & |
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35 | TRACER_MODE, & |
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36 | planet_type, & |
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37 | P_ALBEDO,P_TI,P_CO2ICE,P_EMISS, & |
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38 | P_H2OICE,P_TSOIL,P_Q2,P_TSURF, & |
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39 | P_FLUXRAD,P_WSTAR,P_ISOIL,P_DSOIL,& |
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40 | P_Z0, CST_Z0, P_GW, & |
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41 | NUM_SOIL_LAYERS, & |
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42 | CST_AL, CST_TI, & |
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43 | isfflx, diff_opt, km_opt, & |
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44 | HR_SW,HR_LW,HR_DYN,DT_RAD,& |
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45 | CLOUDFRAC,TOTCLOUDFRAC,RH, & |
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46 | DQICE,DQVAP,REEVAP,SURFRAIN,ALBEQ,FLUXTOP_DN,FLUXABS_SW,FLUXTOP_LW,FLUXSURF_SW,& |
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47 | FLUXSURF_LW,FLXGRD,DTLSC,DTRAIN,DT_MOIST,H2OICE_REFF,LATENT_HF,& |
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48 | HFMAX,ZMAX,& |
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49 | USTM,HFX,& |
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50 | SLPX,SLPY,RESTART) |
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51 | ! NB: module_lmd_driver_output1.inc : output arguments generated from Registry |
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52 | |
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53 | |
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54 | |
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55 | |
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56 | |
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57 | !================================================================== |
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58 | ! USES |
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59 | !================================================================== |
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60 | USE module_state_description |
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61 | USE module_model_constants |
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62 | USE module_wrf_error |
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63 | !!!!!!!! interface modules |
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64 | USE variables_mod !! to set variables |
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65 | USE update_inputs_physiq_mod !! to set inputs for physiq |
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66 | USE update_outputs_physiq_mod !! to get outputs from physiq |
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67 | USE iniphysiq_mod !! to get iniphysiq subroutine |
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68 | USE callphysiq_mod !! to call the LMD physics |
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69 | !!!!!!!! interface modules |
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70 | |
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71 | !================================================================== |
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72 | IMPLICIT NONE |
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73 | !================================================================== |
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74 | |
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75 | !================================================================== |
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76 | ! VARIABLES |
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77 | !================================================================== |
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78 | |
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79 | CHARACTER(len=10),INTENT(IN) :: planet_type |
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80 | ! WRF Dimensions |
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81 | INTEGER, INTENT(IN ) :: & |
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82 | ids,ide,jds,jde,kds,kde, & |
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83 | ims,ime,jms,jme,kms,kme, & |
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84 | kts,kte,num_tiles, & |
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85 | NUM_SOIL_LAYERS |
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86 | INTEGER, DIMENSION(num_tiles), INTENT(IN) :: & |
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87 | i_start,i_end,j_start,j_end |
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88 | ! Scalars |
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89 | INTEGER, INTENT(IN ) :: JULDAY, itimestep, julyr,id,max_dom,TRACER_MODE |
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90 | INTEGER, INTENT(IN ) :: isfflx,diff_opt,km_opt |
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91 | REAL, INTENT(IN ) :: GMT,dt,dx,dy,RADT |
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92 | REAL, INTENT(IN ) :: CST_AL, CST_TI |
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93 | REAL, INTENT(IN ) :: PTOP |
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94 | ! 2D arrays |
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95 | REAL, DIMENSION( ims:ime, jms:jme ), INTENT(INOUT) :: & |
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96 | MSFT,MSFU,MSFV, & |
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97 | XLAT,XLONG,HT, & |
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98 | MUT, & !total dry air column mass (in Pa) |
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99 | P_ALBEDO,P_TI,P_EMISS, & |
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100 | SLPX,SLPY, & |
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101 | P_CO2ICE,P_H2OICE, & |
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102 | P_TSURF, P_Z0, & |
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103 | P_FLUXRAD,P_WSTAR, & |
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104 | PSFC,TSK |
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105 | REAL, DIMENSION( ims:ime, jms:jme ), INTENT(OUT) :: & |
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106 | HFMAX,ZMAX,& |
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107 | USTM,HFX,TOTCLOUDFRAC,ALBEQ,FLUXTOP_DN,FLUXABS_SW,FLUXTOP_LW,FLUXSURF_SW,& |
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108 | FLUXSURF_LW,FLXGRD,LATENT_HF,REEVAP,SURFRAIN |
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109 | REAL, DIMENSION(kms:kme), INTENT(IN ) :: DNW ! del(eta), depth between full levels in eta variables. |
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110 | ! 3D arrays |
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111 | REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(IN ) :: & |
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112 | dz8w,p8w,p,exner,t,t8w,rho,u,v,z,th,p_hyd,p_hyd_w |
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113 | REAL, DIMENSION( ims:ime, kms:kme, jms:jme ), INTENT(OUT ) :: & |
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114 | RTHPLATEN,RUPLATEN,RVPLATEN, & |
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115 | HR_SW,HR_LW,HR_DYN,DT_RAD,& |
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116 | CLOUDFRAC,RH,DQICE,DQVAP,DTLSC,DTRAIN,DT_MOIST,H2OICE_REFF |
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117 | REAL, DIMENSION( ims:ime, kms:kme+1, jms:jme ), INTENT(INOUT ) :: & |
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118 | P_Q2 |
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119 | REAL, DIMENSION( ims:ime, NUM_SOIL_LAYERS, jms:jme ), INTENT(INOUT ) :: & |
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120 | P_TSOIL,P_ISOIL, P_DSOIL |
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121 | REAL, INTENT(IN ) :: CST_Z0 |
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122 | REAL, DIMENSION( ims:ime, 5, jms:jme ), INTENT(IN ) :: & |
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123 | P_GW |
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124 | ! 4D arrays |
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125 | INTEGER, INTENT(IN ) :: num_3d_s,num_3d_m |
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126 | REAL, DIMENSION( ims:ime, kms:kme, jms:jme, 1:num_3d_s ), INTENT(INOUT ) :: scalar |
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127 | REAL, DIMENSION( ims:ime, kms:kme, jms:jme, 1:num_3d_m ), INTENT(INOUT ) :: moist |
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128 | ! Logical |
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129 | LOGICAL, INTENT(IN ) :: restart |
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130 | |
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131 | !------------------------------------------- |
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132 | ! LOCAL VARIABLES |
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133 | !------------------------------------------- |
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134 | INTEGER :: i,j,k,its,ite,jts,jte,ij,kk |
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135 | INTEGER :: subs,iii |
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136 | |
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137 | |
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138 | ! *** for tracer Mode 20 *** |
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139 | REAL :: tau_decay |
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140 | ! *** ----------------------- *** |
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141 | |
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142 | ! *** for LMD physics |
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143 | ! ------> inputs: |
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144 | INTEGER :: ngrid,nlayer,nq,nsoil |
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145 | REAL :: MY |
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146 | REAL :: phisfi_val |
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147 | LOGICAL :: lastcall |
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148 | ! ---------- |
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149 | |
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150 | ! <------ outputs: |
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151 | ! physical tendencies |
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152 | ! ... intermediate arrays |
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153 | REAL, DIMENSION(:), ALLOCATABLE :: & |
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154 | dz8w_prof,p8w_prof,p_prof,t_prof,t8w_prof, & |
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155 | u_prof,v_prof,z_prof |
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156 | REAL, DIMENSION(:,:), ALLOCATABLE :: q_prof |
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157 | |
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158 | ! Additional control variables |
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159 | INTEGER :: sponge_top,relax,ips,ipe,jps,jpe,kps,kpe |
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160 | REAL :: elaps |
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161 | INTEGER :: test |
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162 | REAL :: wappel_phys |
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163 | LOGICAL, SAVE :: flag_first_restart |
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164 | LOGICAL, SAVE :: firstcall = .true. |
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165 | INTEGER, SAVE :: previous_id = 0 |
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166 | REAL, DIMENSION(:), ALLOCATABLE, SAVE :: dp_save |
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167 | REAL, DIMENSION(:,:), ALLOCATABLE, SAVE :: du_save, dv_save, dt_save |
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168 | REAL, DIMENSION(:,:,:), ALLOCATABLE, SAVE :: dq_save |
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169 | |
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170 | !!!IDEALIZED IDEALIZED |
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171 | REAL :: lat_input, lon_input, ls_input, lct_input |
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172 | LOGICAL :: isles |
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173 | !!!IDEALIZED IDEALIZED |
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174 | |
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175 | REAL :: tk1,tk2 |
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176 | |
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177 | !================================================================== |
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178 | ! CODE |
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179 | !================================================================== |
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180 | |
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181 | print *, '** ',planet_type,'** ENTER WRF-LMD DRIVER' |
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182 | |
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183 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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184 | !! determine here if this is turbulence-resolving or not |
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185 | IF (JULYR .le. 8999) THEN |
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186 | isles = .false. ! "True" LES is not available in this version |
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187 | IF (firstcall .EQV. .true.) PRINT *, '*** REAL-CASE SIMULATION ***' |
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188 | ELSE |
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189 | IF (firstcall .EQV. .true.) PRINT *, '*** IDEALIZED SIMULATION ***' |
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190 | IF ((diff_opt .eq. 2) .and. (km_opt .eq. 2)) THEN |
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191 | IF (firstcall .EQV. .true.) THEN |
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192 | PRINT *, '*** type: LES ***' |
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193 | PRINT *, '*** diff_opt = 2 *** km_opt = 2' |
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194 | PRINT *, '*** forcing is isfflx = ',isfflx |
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195 | ENDIF |
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196 | isles = .true. |
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197 | !! SPECIAL LES |
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198 | ELSE |
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199 | IF (firstcall .EQV. .true.) THEN |
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200 | PRINT *, '*** type: not LES ***' |
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201 | PRINT *, '*** diff_opt = ',diff_opt |
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202 | PRINT *, '*** km_opt = ',km_opt |
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203 | ENDIF |
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204 | isles = .false. |
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205 | !! IDEALIZED, no LES |
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206 | !! cependant, ne veut-on pas pouvoir |
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207 | !! prescrire un flux en idealise ?? |
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208 | ENDIF |
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209 | ENDIF |
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210 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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211 | |
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212 | !-------------------------! |
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213 | ! TWEAK on WRF DIMENSIONS ! |
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214 | !-------------------------! |
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215 | its = i_start(1) ! define here one big tile |
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216 | ite = i_end(num_tiles) |
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217 | jts = j_start(1) |
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218 | jte = j_end(num_tiles) |
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219 | !! |
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220 | IF (isles .eqv. .false.) THEN |
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221 | relax=0 |
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222 | sponge_top=0 ! another value than 0 triggers instabilities |
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223 | IF (id .gt. 1) relax=2 ! fix to avoid noise in nesting simulations ; 1 >> too much noise ... |
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224 | ENDIF |
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225 | ips=its |
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226 | ipe=ite |
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227 | jps=jts |
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228 | jpe=jte |
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229 | IF (isles .eqv. .false.) THEN |
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230 | IF (ips .eq. ids) ips=its+relax !! IF tests necesary for parallel runs |
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231 | IF (ipe .eq. ide-1) ipe=ite-relax |
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232 | IF (jps .eq. jds) jps=jts+relax |
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233 | IF (jpe .eq. jde-1) jpe=jte-relax |
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234 | ENDIF |
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235 | kps=kts !! start at surface |
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236 | IF (isles .eqv. .false.) THEN |
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237 | kpe=kte-sponge_top |
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238 | ELSE |
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239 | IF (firstcall .EQV. .true.) PRINT *, '*** IDEALIZED SIMULATION: LES *** kpe=kte' |
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240 | kpe=kte !-sponge_top |
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241 | ENDIF |
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242 | |
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243 | !----------------------------! |
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244 | ! DIMENSIONS FOR THE PHYSICS ! |
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245 | !----------------------------! |
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246 | wappel_phys = RADT |
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247 | zdt_split = dt*wappel_phys ! physical timestep (s) |
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248 | ngrid=(ipe-ips+1)*(jpe-jps+1) ! size of the horizontal grid |
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249 | nlayer = kpe-kps+1 ! number of vertical layers: nlayermx |
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250 | nsoil = NUM_SOIL_LAYERS ! number of soil layers: nsoilmx |
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251 | CALL update_inputs_physiq_tracers(TRACER_MODE,nq) |
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252 | IF (firstcall .EQV. .true.) PRINT *,'** ',planet_type,'** TRACER MODE', TRACER_MODE |
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253 | |
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254 | ! **** needed but hardcoded |
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255 | lastcall = .false. |
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256 | ! **** needed but hardcoded |
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257 | |
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258 | elaps = (float(itimestep)-1.)*dt ! elapsed seconds of simulation |
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259 | !----------------------------------------------! |
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260 | ! what is done at the first step of simulation ! |
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261 | !----------------------------------------------! |
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262 | IF (elaps .eq. 0.) THEN |
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263 | flag_first_restart = .false. |
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264 | ELSE |
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265 | flag_first_restart=flag_first_restart.OR.(.NOT. ALLOCATED(dp_save)) |
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266 | ENDIF |
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267 | |
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268 | is_first_step: IF ((elaps .eq. 0.).or.flag_first_restart) THEN |
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269 | firstcall=.true. !! for continuity with GCM, physics are always called at the first WRF timestep |
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270 | !firstcall=.false. !! just in case you'd want to get rid of the physics |
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271 | test=0 |
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272 | IF( .NOT. ALLOCATED( dp_save ) ) THEN |
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273 | ALLOCATE(dp_save(ngrid)) !! here are the arrays that would be useful to save physics tendencies |
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274 | ALLOCATE(du_save(ngrid,nlayer)) |
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275 | ALLOCATE(dv_save(ngrid,nlayer)) |
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276 | ALLOCATE(dt_save(ngrid,nlayer)) |
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277 | ALLOCATE(dq_save(ngrid,nlayer,nq)) |
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278 | ENDIF |
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279 | dp_save(:)=0. !! initialize these arrays ... |
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280 | du_save(:,:)=0. |
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281 | dv_save(:,:)=0. |
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282 | dt_save(:,:)=0. |
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283 | dq_save(:,:,:)=0. |
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284 | flag_first_restart=.false. |
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285 | |
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286 | ELSE ! is_first_step |
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287 | !-------------------------------------------------! |
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288 | ! what is done for the other steps of simulation ! |
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289 | !-------------------------------------------------! |
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290 | IF (wappel_phys .gt. 0.) THEN |
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291 | firstcall = .false. |
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292 | test = MODULO(itimestep-1,int(wappel_phys)) ! WRF time is integrated time (itimestep=1 at the end of first step) |
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293 | ! -- same strategy as diagfi in the LMD GCM |
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294 | ! -- arguments of modulo must be of the same kind (here: integers) |
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295 | ELSE |
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296 | firstcall = .false. |
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297 | test = 9999 |
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298 | ENDIF |
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299 | ENDIF is_first_step |
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300 | |
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301 | !------------------------------------! |
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302 | ! print info about domain initially ! |
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303 | ! ... and whenever domain is changed ! |
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304 | !------------------------------------! |
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305 | IF (previous_id .ne. id) THEN |
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306 | print *,'** ',planet_type,' ** DOMAIN',id |
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307 | print *, '** ',planet_type,' ** ... INITIALIZE DOMAIN',id |
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308 | print *, '** ',planet_type,' ** ... PREVIOUS DOMAIN was',previous_id |
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309 | print *, 'ITIMESTEP: ',itimestep |
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310 | print *, 'TILES: ', i_start,i_end, j_start, j_end ! numbers for simple runs, arrays for parallel runs |
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311 | print *, 'DOMAIN: ', ids, ide, jds, jde, kds, kde |
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312 | print *, 'MEMORY: ', ims, ime, jms, jme, kms, kme |
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313 | print *, 'COMPUT: ', ips, ipe, jps, jpe, kps, kpe |
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314 | print *, 'SIZE OF PHYSICS GRID for this process: ',ngrid |
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315 | print *, 'ADVECTED TRACERS: ', num_3d_s-1 |
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316 | print *, 'PHYSICS IS CALLED EACH...',wappel_phys |
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317 | print *, '-- means: PHYSICAL TIMESTEP=',zdt_split |
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318 | ENDIF |
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319 | |
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320 | |
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321 | !!!***********!! |
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322 | !!! IDEALIZED !! |
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323 | !!!***********!! |
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324 | IF (.not.(JULYR .le. 8999)) THEN |
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325 | IF (firstcall .EQV. .true.) THEN |
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326 | PRINT *,'** ',planet_type,'** IDEALIZED SIMULATION' |
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327 | PRINT *,'** ',planet_type,'** BEWARE: input_coord must be here' |
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328 | ENDIF |
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329 | open(unit=14,file='input_coord',form='formatted',status='old') |
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330 | rewind(14) |
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331 | read(14,*) lon_input |
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332 | read(14,*) lat_input |
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333 | read(14,*) ls_input |
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334 | read(14,*) lct_input |
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335 | close(14) |
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336 | ENDIF |
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337 | |
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338 | !----------! |
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339 | ! ALLOCATE ! |
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340 | !----------! |
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341 | CALL allocate_interface(ngrid,nlayer,nq) |
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342 | !!! |
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343 | !!! BIG LOOP : 1. no call for physics, used saved values |
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344 | !!! |
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345 | IF (test.NE.0) THEN |
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346 | print *,'** ',planet_type,'** NO CALL FOR PHYSICS, go to next step...',test |
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347 | print*,'else' |
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348 | zdpsrf_omp(:)=dp_save(:) |
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349 | zdufi_omp(:,:)=du_save(:,:) |
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350 | zdvfi_omp(:,:)=dv_save(:,:) |
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351 | zdtfi_omp(:,:)=dt_save(:,:) |
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352 | zdqfi_omp(:,:,:)=dq_save(:,:,:) |
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353 | !!! |
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354 | !!! BIG LOOP : 2. calculate physical tendencies |
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355 | !!! |
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356 | ELSE ! if (test.EQ.0) |
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357 | !----------! |
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358 | ! ALLOCATE ! |
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359 | !----------! |
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360 | ! interm |
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361 | ALLOCATE(dz8w_prof(nlayer)) |
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362 | ALLOCATE(p8w_prof(nlayer+1)) |
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363 | ALLOCATE(p_prof(nlayer)) |
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364 | ALLOCATE(t_prof(nlayer)) |
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365 | ALLOCATE(t8w_prof(nlayer)) |
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366 | ALLOCATE(u_prof(nlayer)) |
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367 | ALLOCATE(v_prof(nlayer)) |
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368 | ALLOCATE(z_prof(nlayer)) |
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369 | ALLOCATE(q_prof(nlayer,nq)) |
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370 | |
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371 | |
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372 | !!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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373 | !!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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374 | !! PREPARE PHYSICS INPUTS !! |
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375 | !!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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376 | !!!!!!!!!!!!!!!!!!!!!!!!!!!! |
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377 | |
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378 | !! INITIALIZE AND ALLOCATE EVERYTHING !! here, only firstcall |
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379 | allocation_firstcall: IF (firstcall .EQV. .true.) THEN |
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380 | !! PHYSICS VARIABLES (cf. iniphysiq in LMD GCM) |
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381 | !! parameters are defined in the module_model_constants.F WRF routine |
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382 | PRINT *,'** ',planet_type,'** INITIALIZE ARRAYS FOR PHYSICS' |
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383 | !! need to get initial time first |
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384 | CALL update_inputs_physiq_time(& |
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385 | JULYR,JULDAY,GMT,& |
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386 | elaps,& |
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387 | lct_input,lon_input,ls_input,& |
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388 | MY) |
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389 | !! Set up initial time |
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390 | phour_ini = JH_cur_split |
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391 | !! Fill planetary parameters in modules |
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392 | !! Values defined in the module_model_constants.F WRF routine |
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393 | CALL update_inputs_physiq_constants |
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394 | !! JL21 it seems nothing is done in update_inputs_physiq_constants for generic case !!! |
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395 | !! Initialize physics |
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396 | CALL iniphysiq(ngrid,nlayer,nq,wappel_phys,& |
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397 | wdaysec,floor(JD_cur), & |
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398 | 1./reradius,g,r_d,cp,1) |
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399 | |
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400 | |
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401 | ENDIF allocation_firstcall |
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402 | |
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403 | !!*****************************!! |
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404 | !! PREPARE "FOOD" FOR PHYSIQ.F !! |
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405 | !!*****************************!! |
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406 | |
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407 | DO j = jps,jpe |
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408 | DO i = ips,ipe |
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409 | |
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410 | !!*******************************************!! |
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411 | !! FROM 3D WRF FIELDS TO 1D PHYSICS PROFILES !! |
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412 | !!*******************************************!! |
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413 | |
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414 | !-----------------------------------! |
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415 | ! 1D subscript for physics "cursor" ! |
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416 | !-----------------------------------! |
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417 | subs = (j-jps)*(ipe-ips+1)+(i-ips+1) |
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418 | |
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419 | !--------------------------------------! |
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420 | ! 1D columns : inputs for the physics ! |
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421 | ! ... vert. coord., meteor. fields ... ! |
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422 | !--------------------------------------! |
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423 | dz8w_prof(:) = dz8w(i,kps:kpe,j) ! dz between full levels (m) |
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424 | p_prof(:) = p_hyd(i,kps:kpe,j) ! hydrostatic pressure at layers >> zplay_omp |
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425 | p8w_prof(:) = p_hyd_w(i,kps:kpe+1,j) ! hydrostatic pressure at levels |
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426 | !JL22 using hydrostatic pressures to conserve mass |
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427 | t_prof(:) = t(i,kps:kpe,j) ! temperature half level (K) >> pt |
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428 | t8w_prof(:) = t8w(i,kps:kpe,j) ! temperature full level (K) |
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429 | u_prof(:) = u(i,kps:kpe,j) ! zonal wind (A-grid: unstaggered) half level (m/s) >> zufi_omp |
---|
430 | v_prof(:) = v(i,kps:kpe,j) ! meridional wind (A-grid: unstaggered) half level (m/s) >> pv |
---|
431 | z_prof(:) = z(i,kps:kpe,j) ! geopotential height half level (m) >> zphi_omp/g |
---|
432 | |
---|
433 | |
---|
434 | !--------------------------------! |
---|
435 | ! specific treatment for tracers ! |
---|
436 | !--------------------------------! |
---|
437 | IF (TRACER_MODE == 1) THEN |
---|
438 | ! to be clean we should have an automatized process that makes sure that moist is sent to igcm_h2o_vap and etc. |
---|
439 | q_prof(:,1) = SCALAR(i,kps:kpe,j,P_QH2O) / (1.d0 + SCALAR(i,kps:kpe,j,P_QH2O)) !! P_xxx is the index for variable xxx. |
---|
440 | q_prof(:,2) = SCALAR(i,kps:kpe,j,P_QH2O_ICE) / (1.d0 + SCALAR(i,kps:kpe,j,P_QH2O)) |
---|
441 | ! conversion from mass mixing ratio in WRF to specific concentration in Physiq |
---|
442 | ELSE IF ((TRACER_MODE >= 42).AND.(TRACER_MODE <= 45)) THEN |
---|
443 | ! to be clean we should have an automatized process that makes sure that moist is sent to igcm_h2o_vap and etc. |
---|
444 | q_prof(:,1) = moist(i,kps:kpe,j,P_QV) / (1.d0 + moist(i,kps:kpe,j,P_QV)) !! P_xxx is the index for variable xxx. |
---|
445 | q_prof(:,2) = moist(i,kps:kpe,j,P_QC) / (1.d0 + moist(i,kps:kpe,j,P_QV)) |
---|
446 | ! conversion from mass mixing ratio in WRF to specific concentration in Physiq |
---|
447 | ELSE |
---|
448 | q_prof(:,1:nq) = SCALAR(i,kps:kpe,j,2:nq+1) !! the names were set above !! one dummy tracer in WRF |
---|
449 | !JL22 cannot normalize to moist here as we do not know if it has been initialized. |
---|
450 | ENDIF |
---|
451 | |
---|
452 | IF (firstcall .EQV. .true.) THEN |
---|
453 | !-----------------! |
---|
454 | ! Optional output ! |
---|
455 | !-----------------! |
---|
456 | IF ( (i == ips) .AND. (j == jps) ) THEN |
---|
457 | PRINT *,'z_prof ',z_prof |
---|
458 | PRINT *,'dz8w_prof',dz8w_prof |
---|
459 | PRINT *,'p8w_prof ',p8w_prof |
---|
460 | PRINT *,'p_prof ',p_prof |
---|
461 | PRINT *,'t_prof ',t_prof |
---|
462 | PRINT *,'t8w_prof ',t8w_prof |
---|
463 | PRINT *,'u_prof ',u_prof |
---|
464 | PRINT *,'v_prof ',v_prof |
---|
465 | PRINT *,'q_prof ',q_prof |
---|
466 | ENDIF |
---|
467 | ENDIF |
---|
468 | |
---|
469 | !---------------------------------------------! |
---|
470 | ! in LMD physics, geopotential must be ! |
---|
471 | ! expressed with respect to the local surface ! |
---|
472 | !---------------------------------------------! |
---|
473 | zphi_omp(subs,:) = g*( z_prof(:)-(z_prof(1)-dz8w_prof(1)/2.) ) |
---|
474 | |
---|
475 | !--------------------------------! |
---|
476 | ! Dynamic fields for LMD physics ! |
---|
477 | !--------------------------------! |
---|
478 | zplev_omp(subs,1:nlayer+1) = p8w_prof(1:nlayer+1) !! NB: last level: no data |
---|
479 | zplay_omp(subs,:) = p_prof(:) |
---|
480 | ztfi_omp(subs,:) = t_prof(:) |
---|
481 | zufi_omp(subs,:) = u_prof(:) |
---|
482 | zvfi_omp(subs,:) = v_prof(:) |
---|
483 | flxwfi_omp(subs,:) = 0 !! NB: not used in the physics, only diagnostic... |
---|
484 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
485 | !! for IDEALIZED CASES ONLY |
---|
486 | !IF (.not.(JULYR .le. 8999)) zplev_omp(subs,nlayer+1)=0. !! zplev_omp(subs,nlayer+1)=ptop >> NO ! |
---|
487 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
488 | |
---|
489 | ! NOTE: |
---|
490 | ! IF ( zplev_omp(subs,nlayer+1) .le. 0 ) zplev_omp(subs,nlayer+1)=ptop |
---|
491 | ! cree des diagnostics delirants et aleatoires dans le transfert radiatif |
---|
492 | |
---|
493 | !---------! |
---|
494 | ! Tracers ! |
---|
495 | !---------! |
---|
496 | zqfi_omp(subs,:,:) = q_prof(:,:) !! traceurs generiques, seuls noms sont specifiques |
---|
497 | |
---|
498 | ENDDO |
---|
499 | ENDDO |
---|
500 | |
---|
501 | !---------------------------------------------------------! |
---|
502 | ! Ground geopotential ! |
---|
503 | ! (=g*HT(i,j), only used in the microphysics: newcondens) ! |
---|
504 | !---------------------------------------------------------! |
---|
505 | phisfi_val=g*(z_prof(1)-dz8w_prof(1)/2.) !! NB: z_prof are half levels, so z_prof(1) is not the surface |
---|
506 | |
---|
507 | !!*****************!! |
---|
508 | !! CLEAN THE PLACE !! |
---|
509 | !!*****************!! |
---|
510 | DEALLOCATE(dz8w_prof) |
---|
511 | DEALLOCATE(z_prof) |
---|
512 | DEALLOCATE(p8w_prof) |
---|
513 | DEALLOCATE(p_prof) |
---|
514 | DEALLOCATE(t_prof) |
---|
515 | DEALLOCATE(t8w_prof) |
---|
516 | DEALLOCATE(u_prof) |
---|
517 | DEALLOCATE(v_prof) |
---|
518 | DEALLOCATE(q_prof) |
---|
519 | |
---|
520 | |
---|
521 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
522 | !!! ONE DOMAIN CASE |
---|
523 | !!! --> we simply need to initialize static and physics inputs |
---|
524 | !!! SEVERAL DOMAINS |
---|
525 | !!! --> we update static and physics inputs each time |
---|
526 | !!! to account for domain change |
---|
527 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
528 | pass_interface: IF ( (firstcall .EQV. .true.) .or. (max_dom .GT. 1) ) THEN |
---|
529 | PRINT *,'** ',planet_type,'** PASS INTERFACE. EITHER FIRSTCALL or NESTED SIMULATION.' |
---|
530 | !!*******************************************!! |
---|
531 | !!*******************************************!! |
---|
532 | CALL update_inputs_physiq_geom( & |
---|
533 | ims,ime,jms,jme,& |
---|
534 | ips,ipe,jps,jpe,& |
---|
535 | JULYR,ngrid,nlayer,& |
---|
536 | DX,DY,MSFT,& |
---|
537 | lat_input, lon_input,& |
---|
538 | XLAT,XLONG) |
---|
539 | !!! |
---|
540 | CALL update_inputs_physiq_slope( & |
---|
541 | ims,ime,jms,jme,& |
---|
542 | ips,ipe,jps,jpe,& |
---|
543 | JULYR,& |
---|
544 | SLPX,SLPY) |
---|
545 | !!! |
---|
546 | print*, 'num_soil_layers, nsoil', num_soil_layers, nsoil |
---|
547 | CALL update_inputs_physiq_soil( & |
---|
548 | ims,ime,jms,jme,& |
---|
549 | ips,ipe,jps,jpe,& |
---|
550 | JULYR,nsoil,& |
---|
551 | P_TI,CST_TI,& |
---|
552 | P_ISOIL,P_DSOIL,& |
---|
553 | P_TSOIL,P_TSURF) |
---|
554 | !!! |
---|
555 | CALL update_inputs_physiq_surf( & |
---|
556 | ims,ime,jms,jme,& |
---|
557 | ips,ipe,jps,jpe,& |
---|
558 | JULYR,TRACER_MODE,& |
---|
559 | P_ALBEDO,CST_AL,& |
---|
560 | P_TSURF,P_EMISS,P_CO2ICE,& |
---|
561 | P_GW,P_Z0,CST_Z0,& |
---|
562 | P_H2OICE,& |
---|
563 | phisfi_val) |
---|
564 | !!! |
---|
565 | CALL update_inputs_physiq_turb( & |
---|
566 | ims,ime,jms,jme,kms,kme,& |
---|
567 | ips,ipe,jps,jpe,& |
---|
568 | RESTART,isles,& |
---|
569 | P_Q2,P_WSTAR) |
---|
570 | !!! |
---|
571 | CALL update_inputs_physiq_rad( & |
---|
572 | ims,ime,jms,jme,& |
---|
573 | ips,ipe,jps,jpe,& |
---|
574 | RESTART,& |
---|
575 | P_FLUXRAD) |
---|
576 | !!! |
---|
577 | ENDIF pass_interface |
---|
578 | !!*******************************************!! |
---|
579 | !!*******************************************!! |
---|
580 | |
---|
581 | !!!!!!!!!!!!!!!!!!!!!! |
---|
582 | !!!!!!!!!!!!!!!!!!!!!! |
---|
583 | !! CALL LMD PHYSICS !! |
---|
584 | !!!!!!!!!!!!!!!!!!!!!! |
---|
585 | !!!!!!!!!!!!!!!!!!!!!! |
---|
586 | |
---|
587 | !!! initialize tendencies (security) |
---|
588 | zdpsrf_omp(:)=0. |
---|
589 | zdufi_omp(:,:)=0. |
---|
590 | zdvfi_omp(:,:)=0. |
---|
591 | zdtfi_omp(:,:)=0. |
---|
592 | zdqfi_omp(:,:,:)=0. |
---|
593 | |
---|
594 | call_physics : IF (wappel_phys .ne. 0.) THEN |
---|
595 | !print *, '** ',planet_type,'** CALL TO LMD PHYSICS' |
---|
596 | !!! |
---|
597 | |
---|
598 | CALL update_inputs_physiq_time(& |
---|
599 | JULYR,JULDAY,GMT,& |
---|
600 | elaps,& |
---|
601 | lct_input,lon_input,ls_input,& |
---|
602 | MY) |
---|
603 | !!! |
---|
604 | CALL call_physiq(planet_type,ngrid,nlayer,nq, & |
---|
605 | firstcall,lastcall) |
---|
606 | !!! |
---|
607 | |
---|
608 | !---------------------------------------------------------------------------------! |
---|
609 | ! PHYSIQ TENDENCIES ARE SAVED TO BE SPLIT WITHIN INTERMEDIATE DYNAMICAL TIMESTEPS ! |
---|
610 | !---------------------------------------------------------------------------------! |
---|
611 | dp_save(:)=zdpsrf_omp(:) |
---|
612 | du_save(:,:)=zdufi_omp(:,:) |
---|
613 | dv_save(:,:)=zdvfi_omp(:,:) |
---|
614 | dt_save(:,:)=zdtfi_omp(:,:) |
---|
615 | dq_save(:,:,:)=zdqfi_omp(:,:,:) |
---|
616 | |
---|
617 | !! OUTPUT OUTPUT OUTPUT |
---|
618 | !-------------------------------------------------------! |
---|
619 | ! Save key variables for restart and output and nesting ! |
---|
620 | !-------------------------------------------------------! |
---|
621 | !!! |
---|
622 | CALL update_outputs_physiq_surf( & |
---|
623 | ims,ime,jms,jme,& |
---|
624 | ips,ipe,jps,jpe,& |
---|
625 | TRACER_MODE,& |
---|
626 | P_TSURF,P_CO2ICE,& |
---|
627 | P_H2OICE) |
---|
628 | !!! |
---|
629 | CALL update_outputs_physiq_soil( & |
---|
630 | ims,ime,jms,jme,& |
---|
631 | ips,ipe,jps,jpe,& |
---|
632 | nsoil,& |
---|
633 | P_TSOIL) |
---|
634 | !!! |
---|
635 | CALL update_outputs_physiq_rad( & |
---|
636 | ims,ime,jms,jme,& |
---|
637 | ips,ipe,jps,jpe,& |
---|
638 | P_FLUXRAD) |
---|
639 | !!! |
---|
640 | CALL update_outputs_physiq_turb( & |
---|
641 | ims,ime,jms,jme,kms,kme,& |
---|
642 | ips,ipe,jps,jpe,kps,kpe,& |
---|
643 | P_Q2,P_WSTAR,& |
---|
644 | HFMAX,ZMAX,USTM,HFX) |
---|
645 | !!! |
---|
646 | CALL update_outputs_physiq_diag( & |
---|
647 | ims,ime,jms,jme,kms,kme,& |
---|
648 | ips,ipe,jps,jpe,kps,kpe,& |
---|
649 | HR_SW,HR_LW,HR_DYN,DT_RAD,& |
---|
650 | CLOUDFRAC,TOTCLOUDFRAC,RH,& |
---|
651 | DQICE,DQVAP,REEVAP,SURFRAIN,& |
---|
652 | ALBEQ,FLUXTOP_DN,FLUXABS_SW,FLUXTOP_LW,FLUXSURF_SW,& |
---|
653 | FLUXSURF_LW,FLXGRD,DTLSC,DTRAIN,DT_MOIST,H2OICE_REFF,LATENT_HF) |
---|
654 | !!! |
---|
655 | !print *, '** ',planet_type,'** OUTPUT PHYSICS DONE' |
---|
656 | |
---|
657 | ENDIF call_physics |
---|
658 | |
---|
659 | ENDIF ! end of BIG LOOP 2. |
---|
660 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
661 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
662 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
663 | !!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!!! |
---|
664 | |
---|
665 | !!***************************!! |
---|
666 | !! DEDUCE TENDENCIES FOR WRF !! |
---|
667 | !!***************************!! |
---|
668 | RTHPLATEN(ims:ime,kms:kme,jms:jme)=0. |
---|
669 | RUPLATEN(ims:ime,kms:kme,jms:jme)=0. |
---|
670 | RVPLATEN(ims:ime,kms:kme,jms:jme)=0. |
---|
671 | PSFC(ims:ime,jms:jme)=p8w(ims:ime,kms,jms:jme) ! was done in surface driver in regular WRF |
---|
672 | !------------------------------------------------------------------! |
---|
673 | ! WRF adds the physical and dynamical tendencies ! |
---|
674 | ! thus the tendencies must be passed as 'per second' tendencies ! |
---|
675 | ! --when physics is not called, the applied physical tendency ! |
---|
676 | ! --is the one calculated during the last call to physics ! |
---|
677 | !------------------------------------------------------------------! |
---|
678 | !print*,'pdt',pdt(1,1),pdt(1,nlayer) |
---|
679 | !print*,'exner',exner(1,:,1) |
---|
680 | DO j = jps,jpe |
---|
681 | DO i = ips,ipe |
---|
682 | |
---|
683 | subs = (j-jps)*(ipe-ips+1)+(i-ips+1) |
---|
684 | |
---|
685 | ! zonal wind |
---|
686 | RUPLATEN(i,kps:kpe,j) = zdufi_omp(subs,kps:kpe) |
---|
687 | ! meridional wind |
---|
688 | RVPLATEN(i,kps:kpe,j) = zdvfi_omp(subs,kps:kpe) |
---|
689 | ! potential temperature |
---|
690 | ! (dT = dtheta * exner for isobaric coordinates or if pressure variations are negligible) |
---|
691 | RTHPLATEN(i,kps:kpe,j) = zdtfi_omp(subs,kps:kpe) / exner(i,kps:kpe,j) |
---|
692 | ! update surface pressure (cf CO2 cycle in physics) |
---|
693 | ! here dt is needed |
---|
694 | PSFC(i,j)=PSFC(i,j)+zdpsrf_omp(subs)*dt |
---|
695 | ! tracers |
---|
696 | SCALAR(i,kps:kpe,j,1)=0. |
---|
697 | SELECT CASE (TRACER_MODE) |
---|
698 | CASE(0) |
---|
699 | SCALAR(i,kps:kpe,j,:)=0. |
---|
700 | CASE(1) |
---|
701 | scalar(i,kps:kpe,j,P_QH2O)=scalar(i,kps:kpe,j,P_QH2O) & |
---|
702 | +zdqfi_omp(subs,kps:kpe,1)*dt * (1.d0+scalar(i,kps:kpe,j,P_QH2O)) |
---|
703 | scalar(i,kps:kpe,j,P_QH2O_ICE)=scalar(i,kps:kpe,j,P_QH2O_ICE) & |
---|
704 | +zdqfi_omp(subs,kps:kpe,2)*dt * (1.d0+scalar(i,kps:kpe,j,P_QH2O)) |
---|
705 | ! if you want to use this mode, RTHPLATEN should be corrected as below. |
---|
706 | ! we keep it like that for the moment for testing. |
---|
707 | CASE(42) |
---|
708 | moist(i,kps:kpe,j,P_QV)=moist(i,kps:kpe,j,P_QV) & |
---|
709 | +zdqfi_omp(subs,kps:kpe,1)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
710 | moist(i,kps:kpe,j,P_QC)=moist(i,kps:kpe,j,P_QC) & |
---|
711 | +zdqfi_omp(subs,kps:kpe,2)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
712 | RTHPLATEN(i,kps:kpe,j) = RTHPLATEN(i,kps:kpe,j) & |
---|
713 | * (1.d0+moist(i,kps:kpe,j,P_QV))/(1.d0+rvovrd*moist(i,kps:kpe,j,P_QV)) |
---|
714 | ! correct dT/dt assuming a constant molar heat capacity. |
---|
715 | ! Specific heat cappacity scales with molar mass. |
---|
716 | CASE(43) |
---|
717 | moist(i,kps:kpe,j,P_QV)=moist(i,kps:kpe,j,P_QV) & |
---|
718 | +zdqfi_omp(subs,kps:kpe,1)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
719 | moist(i,kps:kpe,j,P_QC)=moist(i,kps:kpe,j,P_QC) & |
---|
720 | +zdqfi_omp(subs,kps:kpe,2)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
721 | tau_decay=86400.*100. !! why not make it a namelist argument? |
---|
722 | SCALAR(i,kps:kpe,j,P_MARKER) = SCALAR(i,kps:kpe,j,P_MARKER)*exp(-dt/tau_decay) |
---|
723 | SCALAR(i,1,j,P_MARKER) = 1. !! this tracer is emitted in the surface layer |
---|
724 | RTHPLATEN(i,kps:kpe,j) = RTHPLATEN(i,kps:kpe,j) & |
---|
725 | * (1.d0+moist(i,kps:kpe,j,P_QV))/(1.d0+rvovrd*moist(i,kps:kpe,j,P_QV)) |
---|
726 | ! correct dT/dt assuming a constant molar heat capacity. |
---|
727 | ! Specific heat cappacity scales with molar mass. |
---|
728 | CASE(44) |
---|
729 | moist(i,kps:kpe,j,P_QV)=moist(i,kps:kpe,j,P_QV) & |
---|
730 | +zdqfi_omp(subs,kps:kpe,1)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
731 | moist(i,kps:kpe,j,P_QC)=moist(i,kps:kpe,j,P_QC) & |
---|
732 | +zdqfi_omp(subs,kps:kpe,2)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
733 | CASE(45) |
---|
734 | moist(i,kps:kpe,j,P_QV)=moist(i,kps:kpe,j,P_QV) & |
---|
735 | +zdqfi_omp(subs,kps:kpe,1)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
736 | moist(i,kps:kpe,j,P_QC)=moist(i,kps:kpe,j,P_QC) & |
---|
737 | +zdqfi_omp(subs,kps:kpe,2)*dt * (1.d0+moist(i,kps:kpe,j,P_QV)) |
---|
738 | tau_decay=86400.*100. !! why not make it a namelist argument? |
---|
739 | SCALAR(i,kps:kpe,j,P_MARKER) = SCALAR(i,kps:kpe,j,P_MARKER)*exp(-dt/tau_decay) |
---|
740 | SCALAR(i,1,j,P_MARKER) = 1. !! this tracer is emitted in the surface layer |
---|
741 | CASE DEFAULT |
---|
742 | !SCALAR(i,kps:kpe,j,2:nq+1)=SCALAR(i,kps:kpe,j,2:nq+1)+zdqfi_omp(subs,kps:kpe,1:nq)*dt !!! here dt is needed |
---|
743 | scalar(i,kps:kpe,j,2:nq+1)=scalar(i,kps:kpe,j,2:nq+1) & |
---|
744 | +zdqfi_omp(subs,kps:kpe,1:nq)*dt |
---|
745 | END SELECT |
---|
746 | |
---|
747 | ENDDO |
---|
748 | ENDDO |
---|
749 | CALL deallocate_interface |
---|
750 | !!*****!! |
---|
751 | !! END !! |
---|
752 | !!*****!! |
---|
753 | !print *,'** ',planet_type,'** END LMD PHYSICS' |
---|
754 | previous_id = id |
---|
755 | !----------------------------------------------------------------! |
---|
756 | ! use debug (see solve_em) if you wanna display some message ... ! |
---|
757 | !----------------------------------------------------------------! |
---|
758 | END SUBROUTINE lmd_driver |
---|
759 | |
---|
760 | END MODULE module_lmd_driver |
---|