1 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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2 | |
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3 | ! Nouveau code d'interface entre LMDZ et COSPv2 (version 2) |
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4 | ! L'ancienne interface s'appelait "phys_cosp2" et avait ete concue pour COSPv1.4. |
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5 | ! Dans cette nouvelle version de COSP, le code a ete restructure pour optimiser les calculs |
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6 | ! des differents simulateurs et pour proposer de nouvelles fonctionnalites (par exemple, |
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7 | ! intervenir sur les profils sous-maille, ou subcolumns, donnes en entre a COSP afin que |
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8 | ! leur definition soit coherente avec les parametrisations du modele hote). |
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9 | ! Cette version de COSP propose aussi de nombreux nouveaux diagnostics, notamment pour |
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10 | ! le simulateur lidar (diagnostics CALIPSO-OPAQ, lidar sol 532nm et lidar ATLID 355nm). |
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11 | |
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12 | ! Interface reecrite par R.Guzman (01/2019), a partir de l'interface initiale concue |
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13 | ! et ecrite par A.Idelkadi |
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14 | |
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15 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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16 | ! subroutine phys_cosp2( itap,dtime,freq_cosp, & |
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17 | subroutine lmdz_cosp_interface(itap, dtime, freq_cosp, ok_mensuelCOSP, ok_journeCOSP, & |
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18 | ok_hfCOSP, ecrit_mth, ecrit_day, ecrit_hf, ok_all_xml, & |
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19 | missing_val, Nptslmdz, Nlevlmdz, lon, lat, presnivs, & |
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20 | overlaplmdz, sunlit, ref_liq, ref_ice, fracTerLic, & |
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21 | u_wind, v_wind, phis, phi, ph, p, skt, t, sh, rh, & |
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22 | tca, cca, mr_lsliq, mr_lsice, fl_lsrainI, fl_lssnowI, & |
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23 | fl_ccrainI, fl_ccsnowI, mr_ozone, dtau_s, dem_s) |
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24 | |
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25 | !-------------- Inputs --------------- |
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26 | ! itap, !Increment de la physiq |
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27 | ! dtime, !Pas de temps physiq |
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28 | ! overlaplmdz, !Type Overlap venant de LMDZ |
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29 | ! Npoints, !Nb de points de la grille physiq |
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30 | ! Nlevels, !Nb de niveaux verticaux |
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31 | ! Ncolumns, !Number of subcolumns |
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32 | ! lon,lat, !Longitudes et latitudes de la grille LMDZ |
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33 | ! ref_liq, ref_ice, !Rayons effectifs des particules liq et ice (en micron) |
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34 | ! fracTerLic, !Fraction terre a convertir en masque |
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35 | ! u_wind, v_wind, !Vents a 10m ??? |
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36 | ! phi, !Geopotentiel |
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37 | ! phis, !Geopotentiel sol |
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38 | ! ph, !pression pour chaque inter-couche |
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39 | ! p, !Pression aux milieux des couches |
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40 | ! skt, t, !Temp au sol et temp 3D |
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41 | ! sh, !Humidite specifique |
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42 | ! rh, !Humidite relative |
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43 | ! tca, !Fraction nuageuse |
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44 | ! cca !Fraction nuageuse convective |
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45 | ! mr_lsliq, !Liq Cloud water content |
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46 | ! mr_lsice, !Ice Cloud water content |
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47 | ! mr_ccliq, !Convective Cloud Liquid water content |
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48 | ! mr_ccice, !Cloud ice water content |
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49 | ! fl_lsrain, !Large scale precipitation lic |
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50 | ! fl_lssnow, !Large scale precipitation ice |
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51 | ! fl_ccrain, !Convective precipitation lic |
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52 | ! fl_ccsnow, !Convective precipitation ice |
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53 | ! mr_ozone, !Concentration ozone (Kg/Kg) |
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54 | ! dem_s !Cloud optical emissivity |
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55 | ! dtau_s !Cloud optical thickness |
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56 | ! emsfc_lw = 1. !Surface emissivity dans radlwsw.F90 |
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57 | |
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58 | |
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59 | !-------------- Outputs -------------- |
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60 | ! La liste complete des diagnostics de sortie (observables simulees) que l'on peut |
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61 | ! avoir avec COSPv2 se trouve au debut du fichier : cosp_read_otputkeys.F90 |
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62 | |
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63 | |
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64 | !!! Modules specifiques a l'interface LMDZ-COSP |
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65 | use lmdz_phys_para |
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66 | use lmdz_grid_phy |
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67 | use ioipsl |
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68 | use iophy |
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69 | use lmdz_xios, ONLY : using_xios |
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70 | use lmdz_cosp_output_mod |
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71 | use lmdz_cosp_output_write_mod |
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72 | use lmdz_cosp_read_outputkeys |
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73 | use lmdz_cosp_subsample_and_optics_mod, only : subsample_and_optics |
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74 | use lmdz_cosp_construct_destroy_mod |
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75 | |
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76 | !!! Modules faisant partie du code source de COSPv2 |
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77 | use cosp_kinds, only: wp |
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78 | use MOD_COSP_CONFIG, only: N_HYDRO,RTTOV_MAX_CHANNELS, & |
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79 | niv_sorties, vgrid_z_in |
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80 | use mod_quickbeam_optics, only: size_distribution,hydro_class_init, & |
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81 | quickbeam_optics_init |
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82 | use quickbeam, only: radar_cfg |
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83 | use mod_cosp, only: cosp_init,cosp_optical_inputs, & |
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84 | cosp_column_inputs,cosp_outputs, & |
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85 | cosp_simulator |
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86 | |
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87 | |
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88 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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89 | |
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90 | ! Declaration des variables |
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91 | |
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92 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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93 | |
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94 | IMPLICIT NONE |
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95 | |
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96 | ! Local variables |
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97 | character(len=64),PARAMETER :: cosp_input_nl = 'cospv2_input_nl.txt' |
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98 | character(len=64),PARAMETER :: cosp_output_nl = 'cospv2_output_nl.txt' |
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99 | |
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100 | integer, save :: isccp_topheight, isccp_topheight_direction, overlap |
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101 | integer, save :: Ncolumns ! Number of subcolumns in SCOPS |
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102 | integer, save :: Npoints ! Number of gridpoints |
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103 | !$OMP THREADPRIVATE(Npoints) |
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104 | integer, save :: Nlevels ! Number of model vertical levels |
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105 | integer :: Nptslmdz, Nlevlmdz ! Nb de points issus de physiq.F |
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106 | integer, save :: Npoints_it ! Max number of gridpoints to be |
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107 | ! processed in one iteration |
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108 | type(cosp_config), save :: cfg ! Variable qui contient les cles |
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109 | ! logiques des simulateurs et des |
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110 | ! diagnostics, definie dans: |
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111 | ! lmdz_cosp_construct_destroy_mod |
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112 | !$OMP THREADPRIVATE(cfg) |
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113 | |
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114 | integer :: t0, t1, count_rate, count_max |
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115 | real(wp), save :: cloudsat_radar_freq, cloudsat_k2, rttov_ZenAng, co2, & |
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116 | ch4, n2o, co, emsfc_lw |
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117 | !$OMP THREADPRIVATE(emsfc_lw) |
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118 | |
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119 | integer, dimension(RTTOV_MAX_CHANNELS), save :: rttov_Channels |
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120 | real(wp), dimension(RTTOV_MAX_CHANNELS), save :: rttov_Surfem |
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121 | integer, save :: surface_radar, use_mie_tables, & |
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122 | cloudsat_use_gas_abs, cloudsat_do_ray, & |
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123 | melt_lay |
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124 | integer, save :: lidar_ice_type |
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125 | integer, save :: rttov_platform, rttov_satellite, & |
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126 | rttov_Instrument, rttov_Nchannels |
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127 | logical, save :: use_vgrid_in, csat_vgrid_in, & |
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128 | use_precipitation_fluxes |
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129 | |
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130 | ! Declaration necessaires pour les sorties IOIPSL |
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131 | REAL :: ecrit_day, ecrit_hf, ecrit_mth, missing_val |
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132 | logical :: ok_mensuelCOSP, ok_journeCOSP, ok_hfCOSP, ok_all_xml |
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133 | logical, save :: debut_cosp=.true. |
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134 | !$OMP THREADPRIVATE(debut_cosp) |
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135 | |
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136 | logical, save :: first_write=.true. |
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137 | !$OMP THREADPRIVATE(first_write) |
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138 | |
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139 | integer, save :: cosp_init_flag = 0 |
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140 | !$OMP THREADPRIVATE(cosp_init_flag) |
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141 | |
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142 | |
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143 | !----------------------------- Input variables from LMDZ-GCM ------------------------------- |
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144 | integer :: overlaplmdz ! overlap type: 1=max, |
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145 | ! 2=rand, 3=max/rand |
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146 | real, dimension(Nptslmdz,Nlevlmdz) :: phi, p, ph, T, sh, rh, tca, cca, mr_lsliq, & |
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147 | mr_lsice, mr_ccliq, mr_ccice, fl_lsrain, & |
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148 | fl_lssnow, fl_ccrain, fl_ccsnow, fl_lsgrpl, & |
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149 | zlev, zlev_half, mr_ozone, radliq, radice, & |
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150 | dtau_s, dem_s, dtau_c, dem_c, ref_liq, ref_ice |
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151 | real, dimension(Nptslmdz,Nlevlmdz) :: fl_lsrainI, fl_lssnowI, fl_ccrainI, fl_ccsnowI |
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152 | real, dimension(Nptslmdz) :: lon, lat, skt, fracTerLic, u_wind, v_wind, & |
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153 | phis, sunlit |
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154 | real, dimension(Nptslmdz) :: land ! variables intermediaire pour masque TerLic |
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155 | real, dimension(Nlevlmdz) :: presnivs |
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156 | integer :: itap, k, ip |
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157 | REAL :: dtime, freq_cosp |
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158 | real, dimension(2) :: time_bnds |
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159 | |
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160 | double precision :: d_dtime |
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161 | double precision, dimension(2) :: d_time_bnds |
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162 | |
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163 | |
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164 | ! ###################################################################################### |
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165 | ! Declarations specific to COSP2 |
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166 | ! ###################################################################################### |
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167 | |
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168 | ! Local variables |
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169 | logical :: & |
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170 | Lsingle = .true., & ! True if using MMF_v3_single_moment CLOUDSAT |
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171 | ! microphysical scheme (default) |
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172 | Ldouble = .false. ! True if using MMF_v3.5_two_moment CLOUDSAT |
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173 | ! microphysical scheme |
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174 | type(size_distribution), save :: sd ! Hydrometeor description |
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175 | !$OMP THREADPRIVATE(sd) |
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176 | type(radar_cfg), save :: rcfg_cloudsat ! Radar configuration |
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177 | !$OMP THREADPRIVATE(rcfg_cloudsat) |
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178 | real, dimension(Nptslmdz,Nlevlmdz,N_HYDRO) :: Reff ! Liquid and Ice particles |
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179 | ! effective radius |
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180 | type(cosp_outputs) :: cospOUT ! COSP simulator outputs |
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181 | type(cosp_optical_inputs) :: cospIN ! COSP optical (or derived?) |
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182 | ! fields needed by simulators |
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183 | type(cosp_column_inputs) :: cospstateIN ! COSP model fields needed |
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184 | ! by simulators |
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185 | character(len=256), dimension(100) :: cosp_status |
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186 | character(len=64), save :: cloudsat_micro_scheme |
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187 | |
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188 | ! Indices to address arrays of LS and CONV hydrometeors |
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189 | integer,parameter :: & |
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190 | I_LSCLIQ = 1, & ! Large-scale (stratiform) liquid |
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191 | I_LSCICE = 2, & ! Large-scale (stratiform) ice |
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192 | I_LSRAIN = 3, & ! Large-scale (stratiform) rain |
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193 | I_LSSNOW = 4, & ! Large-scale (stratiform) snow |
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194 | I_CVCLIQ = 5, & ! Convective liquid |
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195 | I_CVCICE = 6, & ! Convective ice |
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196 | I_CVRAIN = 7, & ! Convective rain |
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197 | I_CVSNOW = 8, & ! Convective snow |
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198 | I_LSGRPL = 9 ! Large-scale (stratiform) groupel |
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199 | |
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200 | ! Parametres qui sont lus a partir du fichier "cosp_input_nl.txt" |
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201 | namelist/COSP_INPUT/overlap, isccp_topheight, isccp_topheight_direction, & |
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202 | npoints_it, ncolumns, use_vgrid_in, csat_vgrid_in, & |
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203 | cloudsat_radar_freq, surface_radar, use_mie_tables, & |
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204 | cloudsat_use_gas_abs, cloudsat_do_ray, melt_lay, cloudsat_k2, & |
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205 | cloudsat_micro_scheme, lidar_ice_type, use_precipitation_fluxes, & |
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206 | rttov_platform, rttov_satellite, rttov_Instrument, rttov_Nchannels, & |
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207 | rttov_Channels, rttov_Surfem, rttov_ZenAng, co2, ch4, n2o, co |
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208 | |
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209 | !------------------------ Fin declaration des variables ------------------------ |
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210 | |
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211 | |
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212 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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213 | |
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214 | ! 1) Lecture du fichier "cosp_input_nl.txt", parametres d'entree pour COSP |
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215 | |
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216 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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217 | |
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218 | print*,'Entree lmdz_cosp_interface' !phys_cosp2' |
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219 | if (debut_cosp) then |
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220 | NPoints=Nptslmdz |
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221 | Nlevels=Nlevlmdz |
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222 | ! Surface emissivity |
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223 | emsfc_lw = 1. |
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224 | |
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225 | ! Lecture du namelist input |
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226 | ! CALL read_cosp_input |
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227 | IF (is_master) THEN |
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228 | OPEN(10,file=cosp_input_nl,status='old') |
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229 | READ(10,nml=cosp_input) |
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230 | CLOSE(10) |
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231 | ENDIF |
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232 | |
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233 | |
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234 | !$OMP BARRIER |
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235 | CALL bcast(overlap) |
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236 | CALL bcast(isccp_topheight) |
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237 | CALL bcast(isccp_topheight_direction) |
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238 | CALL bcast(npoints_it) |
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239 | CALL bcast(ncolumns) |
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240 | CALL bcast(use_vgrid_in) |
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241 | CALL bcast(csat_vgrid_in) |
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242 | CALL bcast(cloudsat_radar_freq) |
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243 | CALL bcast(surface_radar) |
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244 | CALL bcast(cloudsat_use_gas_abs) |
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245 | CALL bcast(cloudsat_do_ray) |
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246 | CALL bcast(cloudsat_k2) |
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247 | CALL bcast(lidar_ice_type) |
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248 | CALL bcast(use_precipitation_fluxes) |
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249 | CALL bcast(rttov_platform) |
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250 | CALL bcast(rttov_satellite) |
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251 | CALL bcast(rttov_Instrument) |
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252 | CALL bcast(rttov_Nchannels) |
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253 | CALL bcast(rttov_Channels) |
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254 | CALL bcast(rttov_Surfem) |
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255 | CALL bcast(rttov_ZenAng) |
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256 | CALL bcast(co2) |
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257 | CALL bcast(ch4) |
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258 | CALL bcast(n2o) |
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259 | CALL bcast(co) |
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260 | CALL bcast(cloudsat_micro_scheme) |
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261 | |
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262 | print*,'ok read cosp_input_nl' |
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263 | |
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264 | ! Clefs Outputs initialisation |
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265 | IF (using_xios) THEN |
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266 | call cosp_outputkeys_init(cfg) |
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267 | ELSE |
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268 | call read_cosp_output_nl(itap,cosp_output_nl,cfg) |
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269 | ENDIF |
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270 | |
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271 | print*,' Cles des differents simulateurs cosp a itap :',itap |
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272 | print*,'cfg%Lcloudsat, cfg%Lcalipso, cfg%LgrLidar532, cfg%Latlid, cfg%Lparasol, & |
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273 | cfg%Lisccp, cfg%Lmisr, cfg%Lmodis, cfg%Lrttov', & |
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274 | cfg%Lcloudsat, cfg%Lcalipso, cfg%LgrLidar532, cfg%Latlid, cfg%Lparasol, & |
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275 | cfg%Lisccp, cfg%Lmisr, cfg%Lmodis, cfg%Lrttov |
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276 | |
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277 | if (overlaplmdz.ne.overlap) then |
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278 | print*,'Attention overlaplmdz different de overlap lu dans namelist ' |
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279 | endif |
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280 | |
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281 | IF (using_xios) THEN |
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282 | print*,'On passe par using_xios' |
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283 | ELSE |
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284 | if (cosp_init_flag .eq. 0) then |
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285 | |
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286 | ! Initialize the distributional parameters for hydrometeors in radar simulator. |
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287 | ! In COSPv1.4, this was declared in cosp_defs.f. |
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288 | if (cloudsat_micro_scheme == 'MMF_v3.5_two_moment') then |
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289 | ldouble = .true. |
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290 | lsingle = .false. |
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291 | endif |
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292 | call hydro_class_init(lsingle,ldouble,sd) |
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293 | call quickbeam_optics_init() |
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294 | |
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295 | print*,' just before call COSP_INIT, cosp_init_flag =', cosp_init_flag |
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296 | call COSP_INIT(cfg%Lisccp, cfg%Lmodis, cfg%Lmisr, cfg%Lcloudsat, cfg%Lcalipso, & |
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297 | cfg%LgrLidar532, cfg%Latlid, cfg%Lparasol, cfg%Lrttov, & |
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298 | cloudsat_radar_freq, cloudsat_k2, cloudsat_use_gas_abs, & |
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299 | cloudsat_do_ray, isccp_topheight, isccp_topheight_direction, & |
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300 | surface_radar, rcfg_cloudsat, use_vgrid_in, csat_vgrid_in, & |
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301 | niv_sorties, Nlevels, cloudsat_micro_scheme) |
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302 | cosp_init_flag = 1 |
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303 | print*,' just after call COSP_INIT, cosp_init_flag =', cosp_init_flag |
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304 | endif |
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305 | ENDIF |
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306 | |
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307 | print*,'Fin lecture Namelists, debut_cosp =',debut_cosp |
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308 | |
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309 | endif ! debut_cosp |
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310 | |
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311 | |
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312 | !!! Ici on modifie les cles logiques pour les outputs selon les champs actives dans les .xml |
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313 | if ((itap.ge.1).and.(first_write))then |
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314 | IF (using_xios) call read_xiosfieldactive(cfg) |
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315 | first_write=.false. |
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316 | |
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317 | if (cosp_init_flag .eq. 0) then |
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318 | |
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319 | ! Initialize the distributional parameters for hydrometeors in radar simulator. |
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320 | ! In COSPv1.4, this was declared in cosp_defs.f. |
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321 | if (cloudsat_micro_scheme == 'MMF_v3.5_two_moment') then |
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322 | ldouble = .true. |
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323 | lsingle = .false. |
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324 | endif |
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325 | call hydro_class_init(lsingle,ldouble,sd) |
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326 | call quickbeam_optics_init() |
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327 | |
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328 | print*,' just before call COSP_INIT, cosp_init_flag =', cosp_init_flag |
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329 | call COSP_INIT(cfg%Lisccp, cfg%Lmodis, cfg%Lmisr, cfg%Lcloudsat, cfg%Lcalipso, & |
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330 | cfg%LgrLidar532, cfg%Latlid, cfg%Lparasol, cfg%Lrttov, & |
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331 | cloudsat_radar_freq, cloudsat_k2, cloudsat_use_gas_abs, & |
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332 | cloudsat_do_ray, isccp_topheight, isccp_topheight_direction, & |
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333 | surface_radar, rcfg_cloudsat, use_vgrid_in, csat_vgrid_in, & |
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334 | niv_sorties, Nlevels, cloudsat_micro_scheme) |
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335 | cosp_init_flag = 1 |
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336 | print*,' just after call COSP_INIT, cosp_init_flag =', cosp_init_flag |
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337 | endif ! cosp_init_flag |
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338 | |
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339 | |
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340 | print*,' Cles des differents simulateurs cosp a itap :',itap |
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341 | print*,'cfg%Lcloudsat, cfg%Lcalipso, cfg%LgrLidar532, cfg%Latlid, cfg%Lparasol, & |
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342 | cfg%Lisccp, cfg%Lmisr, cfg%Lmodis, cfg%Lrttov', & |
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343 | cfg%Lcloudsat, cfg%Lcalipso, cfg%LgrLidar532, cfg%Latlid, cfg%Lparasol, & |
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344 | cfg%Lisccp, cfg%Lmisr, cfg%Lmodis, cfg%Lrttov |
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345 | |
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346 | endif !(itap.gt.1).and.(first_write) |
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347 | |
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348 | time_bnds(1) = dtime-dtime/2. |
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349 | time_bnds(2) = dtime+dtime/2. |
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350 | |
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351 | d_time_bnds=time_bnds |
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352 | d_dtime=dtime |
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353 | |
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354 | !------------------------- Fin initialisation de COSP -------------------------- |
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355 | |
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356 | |
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357 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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358 | |
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359 | ! 3) Calculs des champs d'entree COSP a partir des variables LMDZ |
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360 | |
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361 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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362 | |
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363 | ! 0) Create ptop/ztop for gbx%pf and gbx%zlev are for the the interface, |
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364 | ! also reverse CAM height/pressure values for input into CSOP |
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365 | ! CAM state%pint from top to surface, COSP wants surface to top. |
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366 | |
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367 | ! 0) Altitudes du modele calculees a partir de la variable geopotentiel phi et phis |
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368 | zlev = phi/9.81 |
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369 | |
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370 | zlev_half(:,1) = phis(:)/9.81 |
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371 | DO k = 2, Nlevels |
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372 | DO ip = 1, Npoints |
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373 | zlev_half(ip,k) = phi(ip,k)/9.81 + & |
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374 | (phi(ip,k)-phi(ip,k-1))/9.81 * (ph(ip,k)-p(ip,k)) / (p(ip,k)-p(ip,k-1)) |
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375 | enddo |
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376 | enddo |
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377 | |
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378 | ! 1) Quantite de nuages (couverture?), convectif (=0) et total |
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379 | cca = 0._wp ! convective_cloud_amount (1) |
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380 | tca = tca ! total_cloud_amount (1) |
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381 | |
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382 | ! 2) Humidite relative est donnee tel quel (variable rh) |
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383 | |
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384 | ! 3) Masque terre/mer a partir de la variable fracTerLic |
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385 | DO ip = 1, Npoints |
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386 | if (fracTerLic(ip).ge.0.5) then |
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387 | land(ip) = 1. |
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388 | else |
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389 | land(ip) = 0. |
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390 | endif |
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391 | enddo |
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392 | |
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393 | |
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394 | ! A voir l equivalent LMDZ |
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395 | mr_ccliq = 0.0 |
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396 | mr_ccice = 0.0 |
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397 | !!! gbx%mr_hydro(:,:,I_LSCLIQ) = mr_lsliq !mixing_ratio_large_scale_cloud_liquid (kg/kg) |
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398 | !!! gbx%mr_hydro(:,:,I_LSCICE) = mr_lsice !mixing_ratio_large_scale_cloud_ic |
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399 | !!! gbx%mr_hydro(:,:,I_CVCLIQ) = mr_ccliq !mixing_ratio_convective_cloud_liquid |
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400 | !!! gbx%mr_hydro(:,:,I_CVCICE) = mr_ccice !mixing_ratio_convective_cloud_ice |
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401 | ! A revoir |
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402 | fl_lsrain = fl_lsrainI + fl_ccrainI |
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403 | fl_lssnow = fl_lssnowI + fl_ccsnowI |
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404 | !!! gbx%rain_ls = fl_lsrain !flux_large_scale_cloud_rain (kg m^-2 s^-1) |
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405 | !!! gbx%snow_ls = fl_lssnow !flux_large_scale_cloud_snow |
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406 | ! A voir l equivalent LMDZ |
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407 | fl_lsgrpl = 0. |
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408 | fl_ccsnow = 0. |
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409 | fl_ccrain = 0. |
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410 | !!! gbx%grpl_ls = fl_lsgrpl !flux_large_scale_cloud_graupel |
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411 | !!! gbx%rain_cv = fl_ccrain !flux_convective_cloud_rain |
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412 | !!! gbx%snow_cv = fl_ccsnow !flux_convective_cloud_snow |
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413 | |
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414 | ! ISCCP simulator |
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415 | dtau_c = 0. |
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416 | dem_c = 0. |
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417 | |
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418 | ! note: reff_cosp dimensions should be same as cosp (reff_cosp has 9 hydrometeor dimension) |
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419 | Reff(1:Npoints,1:Nlevels,1:N_HYDRO) = 0. |
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420 | Reff(:,:,I_LSCLIQ) = ref_liq*1e-6 |
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421 | Reff(:,:,I_LSCICE) = ref_ice*1e-6 |
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422 | Reff(:,:,I_CVCLIQ) = ref_liq*1e-6 |
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423 | Reff(:,:,I_CVCICE) = ref_ice*1e-6 |
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424 | |
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425 | |
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426 | if (cosp_init_flag .eq. 1) then ! cosp_init_flag = 1 |
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427 | |
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428 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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429 | |
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430 | ! 4a) On construit la variable cospOUT qui contient tous les diagnostics de sortie. |
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431 | ! Elle sera remplie lors de l'appel du simulateur COSP |
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432 | |
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433 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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434 | |
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435 | call construct_cosp_outputs(cfg,Npoints,Ncolumns,Nlevels,niv_sorties,0,cospOUT) |
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436 | |
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437 | |
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438 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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439 | |
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440 | ! 4b) On construit la variable cospstateIN que l'on va remplir avec les champs LMDZ |
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441 | ! Les champ verticaux doivent etre donnes a l'envers, c-a-d : (Nlevels:1) = (TOA:SFC) |
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442 | |
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443 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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444 | |
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445 | call construct_cospstateIN(Npoints,Nlevels,0,cospstateIN) |
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446 | |
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447 | cospstateIN%lat = lat(1:Npoints) |
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448 | cospstateIN%lon = lon(1:Npoints) |
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449 | cospstateIN%at = t(1:Npoints,Nlevels:1:-1) |
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450 | cospstateIN%qv = sh(1:Npoints,Nlevels:1:-1) |
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451 | cospstateIN%o3 = mr_ozone(1:Npoints,Nlevels:1:-1) |
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452 | cospstateIN%sunlit = sunlit(1:Npoints) |
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453 | cospstateIN%skt = skt(1:Npoints) |
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454 | cospstateIN%land = land(1:Npoints) |
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455 | cospstateIN%surfelev = zlev_half(1:Npoints,1) |
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456 | cospstateIN%pfull = p(1:Npoints,Nlevels:1:-1) |
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457 | cospstateIN%phalf(1:Npoints,1) = 0._wp |
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458 | cospstateIN%phalf(1:Npoints,2:Nlevels+1) = ph(1:Npoints,Nlevels:1:-1) |
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459 | cospstateIN%hgt_matrix = zlev(1:Npoints,Nlevels:1:-1) |
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460 | cospstateIN%hgt_matrix_half(1:Npoints,Nlevels+1) = 0._wp |
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461 | cospstateIN%hgt_matrix_half(1:Npoints,1:Nlevels) = zlev_half(1:Npoints,Nlevels:1:-1) |
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462 | |
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463 | |
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464 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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465 | |
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466 | ! 4c) On construit la variable cospIN qui contient les proprietes optiques subcolumn |
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467 | ! pour COSP. Elle sera essentiellement remplie dans la subroutine subsample_and_optics |
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468 | ! ou sont appeles SCOPS, PREC_SCOPS et les subroutines qui calculent les signaux |
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469 | ! simules pour chaque simulateur actif. |
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470 | |
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471 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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472 | |
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473 | call construct_cospIN(cfg,Npoints,Ncolumns,Nlevels,cospIN) |
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474 | cospIN%emsfc_lw = emsfc_lw |
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475 | if (cfg%Lcloudsat) cospIN%rcfg_cloudsat = rcfg_cloudsat |
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476 | |
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477 | |
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478 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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479 | |
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480 | ! 5) Appel de subsample_and_optics : Les champs verticaux doivent etre donnes a |
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481 | ! l'envers comme pour le remplissage de cospstateIN, c-a-d : (Nlevels:1) = (TOA:SFC) |
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482 | |
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483 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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484 | |
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485 | call subsample_and_optics(cfg, Npoints, Nlevels, Ncolumns, N_HYDRO,overlap, & |
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486 | use_precipitation_fluxes, lidar_ice_type, sd, & |
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487 | tca(1:Npoints,Nlevels:1:-1), cca(1:Npoints,Nlevels:1:-1), & |
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488 | fl_lsrain(1:Npoints,Nlevels:1:-1), & |
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489 | fl_lssnow(1:Npoints,Nlevels:1:-1), & |
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490 | fl_lsgrpl(1:Npoints,Nlevels:1:-1), & |
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491 | fl_ccrain(1:Npoints,Nlevels:1:-1), & |
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492 | fl_ccsnow(1:Npoints,Nlevels:1:-1), & |
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493 | mr_lsliq(1:Npoints,Nlevels:1:-1), & |
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494 | mr_lsice(1:Npoints,Nlevels:1:-1), & |
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495 | mr_ccliq(1:Npoints,Nlevels:1:-1), & |
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496 | mr_ccice(1:Npoints,Nlevels:1:-1), & |
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497 | Reff(1:Npoints,Nlevels:1:-1,:), & |
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498 | dtau_c(1:Npoints,Nlevels:1:-1), & |
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499 | dtau_s(1:Npoints,Nlevels:1:-1), & |
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500 | dem_c(1:Npoints,Nlevels:1:-1), & |
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501 | dem_s(1:Npoints,Nlevels:1:-1), cospstateIN, cospIN) |
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502 | |
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503 | |
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504 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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505 | |
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506 | ! 6) On appelle le simulateur COSPv2 |
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507 | |
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508 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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509 | |
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510 | print*,'call simulateur' |
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511 | |
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512 | cosp_status = COSP_SIMULATOR(cospIN, cospstateIN, cospOUT, 1, Npoints, debug=.false.) |
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513 | |
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514 | endif ! cosp_init_flag = 1 |
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515 | |
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516 | |
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517 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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518 | |
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519 | ! 7a) Ecriture des sorties 1: on cree d'abord les fichiers NCDF pour ecrire les sorties |
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520 | ! en appelant lmdz_cosp_output_open (lors du premier appel de cette interface pour les |
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521 | ! 2 options d'ecriture), ou sont definis les axes et les caracteristiques |
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522 | ! des fichiers de sortie avec les diagnostics. |
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523 | |
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524 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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525 | |
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526 | if (debut_cosp) then |
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527 | !$OMP MASTER |
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528 | |
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529 | print *, ' Open outpts files and define axis' |
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530 | call lmdz_cosp_output_open(Nlevlmdz, Ncolumns, presnivs, dtime, freq_cosp, & |
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531 | ok_mensuelCOSP, ok_journeCOSP, ok_hfCOSP, ok_all_xml, & |
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532 | ecrit_mth, ecrit_day, ecrit_hf, use_vgrid_in, & |
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533 | niv_sorties, vgrid_z_in, zlev(1,:)) |
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534 | |
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535 | !$OMP END MASTER |
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536 | !$OMP BARRIER |
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537 | debut_cosp=.false. |
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538 | endif ! debut_cosp |
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539 | |
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540 | if (cosp_init_flag .eq. 1) then |
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541 | |
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542 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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543 | |
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544 | ! 7b) Ecriture des sorties 2: le remplissage des fichiers de sortie se fait a chaque |
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545 | ! appel de cette interface avec une difference entre les 2 options d'ecriture: |
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546 | |
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547 | ! AVEC xios, on commence a remplir les fichiers de sortie a partir du DEUXIEME |
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548 | ! appel de cette interface (lorsque cosp_init_flag = 1). |
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549 | |
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550 | ! SANS xios, on commence a remplir les fichiers de sortie a partir du PREMIER |
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551 | ! appel de cette interface (lorsque cosp_init_flag = 1). |
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552 | |
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553 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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554 | |
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555 | print *, 'Calling write output' |
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556 | call lmdz_cosp_output_write(Nlevlmdz, Npoints, Ncolumns, itap, dtime, freq_COSP, & |
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557 | missing_val, cfg, niv_sorties, cospOUT) |
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558 | |
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559 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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560 | |
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561 | ! 8) On libere la memoire allouee lors de cet appel a l'interface |
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562 | |
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563 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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564 | |
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565 | call destroy_cospIN(cospIN) |
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566 | call destroy_cospstateIN(cospstateIN) |
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567 | call destroy_cosp_outputs(cospOUT) |
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568 | |
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569 | endif ! cosp_init_flag = 1 |
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570 | |
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571 | end subroutine lmdz_cosp_interface |
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