1 | ! (c) British Crown Copyright 2008, the Met Office. |
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2 | ! All rights reserved. |
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3 | |
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4 | ! Redistribution and use in source and binary forms, with or without modification, are permitted |
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5 | ! provided that the following conditions are met: |
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6 | |
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7 | ! * Redistributions of source code must retain the above copyright notice, this list |
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8 | ! of conditions and the following disclaimer. |
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9 | ! * Redistributions in binary form must reproduce the above copyright notice, this list |
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10 | ! of conditions and the following disclaimer in the documentation and/or other materials |
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11 | ! provided with the distribution. |
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12 | ! * Neither the name of the Met Office nor the names of its contributors may be used |
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13 | ! to endorse or promote products derived from this software without specific prior written |
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14 | ! permission. |
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15 | |
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16 | ! THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR |
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17 | ! IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND |
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18 | ! FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR |
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19 | ! CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL |
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20 | ! DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, |
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21 | ! DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER |
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22 | ! IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT |
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23 | ! OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. |
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24 | |
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25 | #include "cosp_defs.h" |
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26 | MODULE MOD_COSP |
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27 | USE MOD_COSP_TYPES |
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28 | USE MOD_COSP_SIMULATOR |
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29 | USE MOD_COSP_MODIS_SIMULATOR |
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30 | IMPLICIT NONE |
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31 | |
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32 | CONTAINS |
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33 | |
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34 | |
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35 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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36 | !--------------------- SUBROUTINE COSP --------------------------- |
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37 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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38 | !#ifdef RTTOV |
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39 | !SUBROUTINE COSP(overlap,Ncolumns,cfg,vgrid,gbx,sgx,sgradar,sglidar,isccp,misr,modis,rttov,stradar,stlidar) |
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40 | !#else |
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41 | SUBROUTINE COSP(overlap,Ncolumns,cfg,vgrid,gbx,sgx,sgradar,sglidar,isccp,misr,modis,stradar,stlidar) |
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42 | !#endif |
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43 | ! Arguments |
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44 | integer,intent(in) :: overlap ! overlap type in SCOPS: 1=max, 2=rand, 3=max/rand |
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45 | integer,intent(in) :: Ncolumns |
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46 | type(cosp_config),intent(in) :: cfg ! Configuration options |
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47 | type(cosp_vgrid),intent(in) :: vgrid ! Information on vertical grid of stats |
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48 | type(cosp_gridbox),intent(inout) :: gbx |
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49 | type(cosp_subgrid),intent(inout) :: sgx ! Subgrid info |
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50 | type(cosp_sgradar),intent(inout) :: sgradar ! Output from radar simulator |
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51 | type(cosp_sglidar),intent(inout) :: sglidar ! Output from lidar simulator |
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52 | type(cosp_isccp),intent(inout) :: isccp ! Output from ISCCP simulator |
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53 | type(cosp_misr),intent(inout) :: misr ! Output from MISR simulator |
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54 | type(cosp_modis),intent(inout) :: modis ! Output from MODIS simulator |
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55 | !#ifdef RTTOV |
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56 | ! type(cosp_rttov),intent(inout) :: rttov ! Output from RTTOV |
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57 | !#endif |
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58 | type(cosp_radarstats),intent(inout) :: stradar ! Summary statistics from radar simulator |
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59 | type(cosp_lidarstats),intent(inout) :: stlidar ! Summary statistics from lidar simulator |
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60 | |
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61 | ! Local variables |
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62 | integer :: Npoints ! Number of gridpoints |
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63 | integer :: Nlevels ! Number of levels |
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64 | integer :: Nhydro ! Number of hydrometeors |
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65 | integer :: Niter ! Number of calls to cosp_simulator |
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66 | integer :: i_first,i_last ! First and last gridbox to be processed in each iteration |
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67 | integer :: i,Ni |
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68 | integer,dimension(2) :: ix,iy |
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69 | logical :: reff_zero |
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70 | REAL :: maxp,minp |
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71 | integer,dimension(:),allocatable :: & ! Dimensions nPoints |
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72 | seed ! It is recommended that the seed is set to a different value for each model |
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73 | ! gridbox it is called on, as it is possible that the choice of the same |
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74 | ! seed value every time may introduce some statistical bias in the results, |
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75 | ! particularly for low values of NCOL. |
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76 | ! Types used in one iteration |
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77 | type(cosp_gridbox) :: gbx_it |
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78 | type(cosp_subgrid) :: sgx_it |
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79 | type(cosp_vgrid) :: vgrid_it |
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80 | type(cosp_sgradar) :: sgradar_it |
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81 | type(cosp_sglidar) :: sglidar_it |
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82 | type(cosp_isccp) :: isccp_it |
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83 | type(cosp_modis) :: modis_it |
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84 | type(cosp_misr) :: misr_it |
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85 | !#ifdef RTTOV |
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86 | ! type(cosp_rttov) :: rttov_it |
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87 | !#endif |
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88 | type(cosp_radarstats) :: stradar_it |
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89 | type(cosp_lidarstats) :: stlidar_it |
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90 | |
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91 | !++++++++++ Dimensions ++++++++++++ |
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92 | Npoints = gbx%Npoints |
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93 | Nlevels = gbx%Nlevels |
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94 | Nhydro = gbx%Nhydro |
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95 | |
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96 | !++++++++++ Depth of model layers ++++++++++++ |
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97 | DO i=1,Nlevels-1 |
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98 | gbx%dlev(:,i) = gbx%zlev_half(:,i+1) - gbx%zlev_half(:,i) |
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99 | enddo |
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100 | gbx%dlev(:,Nlevels) = 2.0*(gbx%zlev(:,Nlevels) - gbx%zlev_half(:,Nlevels)) |
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101 | |
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102 | !++++++++++ Apply sanity checks to inputs ++++++++++ |
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103 | ! call cosp_check_input('longitude',gbx%longitude,min_val=0.0,max_val=360.0) |
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104 | call cosp_check_input('longitude',gbx%longitude,min_val=-180.0,max_val=180.0) |
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105 | call cosp_check_input('latitude',gbx%latitude,min_val=-90.0,max_val=90.0) |
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106 | call cosp_check_input('dlev',gbx%dlev,min_val=0.0) |
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107 | call cosp_check_input('p',gbx%p,min_val=0.0) |
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108 | call cosp_check_input('ph',gbx%ph,min_val=0.0) |
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109 | call cosp_check_input('T',gbx%T,min_val=0.0) |
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110 | call cosp_check_input('q',gbx%q,min_val=0.0) |
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111 | call cosp_check_input('sh',gbx%sh,min_val=0.0) |
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112 | call cosp_check_input('dtau_s',gbx%dtau_s,min_val=0.0) |
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113 | call cosp_check_input('dtau_c',gbx%dtau_c,min_val=0.0) |
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114 | call cosp_check_input('dem_s',gbx%dem_s,min_val=0.0,max_val=1.0) |
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115 | call cosp_check_input('dem_c',gbx%dem_c,min_val=0.0,max_val=1.0) |
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116 | ! Point information (Npoints) |
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117 | call cosp_check_input('land',gbx%land,min_val=0.0,max_val=1.0) |
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118 | call cosp_check_input('psfc',gbx%psfc,min_val=0.0) |
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119 | call cosp_check_input('sunlit',gbx%sunlit,min_val=0.0,max_val=1.0) |
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120 | call cosp_check_input('skt',gbx%skt,min_val=0.0) |
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121 | ! TOTAL and CONV cloud fraction for SCOPS |
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122 | call cosp_check_input('tca',gbx%tca,min_val=0.0,max_val=1.0) |
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123 | call cosp_check_input('cca',gbx%cca,min_val=0.0,max_val=1.0) |
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124 | ! Precipitation fluxes on model levels |
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125 | call cosp_check_input('rain_ls',gbx%rain_ls,min_val=0.0) |
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126 | call cosp_check_input('rain_cv',gbx%rain_cv,min_val=0.0) |
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127 | call cosp_check_input('snow_ls',gbx%snow_ls,min_val=0.0) |
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128 | call cosp_check_input('snow_cv',gbx%snow_cv,min_val=0.0) |
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129 | call cosp_check_input('grpl_ls',gbx%grpl_ls,min_val=0.0) |
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130 | ! Hydrometeors concentration and distribution parameters |
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131 | call cosp_check_input('mr_hydro',gbx%mr_hydro,min_val=0.0) |
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132 | ! Effective radius [m]. (Npoints,Nlevels,Nhydro) |
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133 | call cosp_check_input('Reff',gbx%Reff,min_val=0.0) |
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134 | reff_zero=.true. |
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135 | if (any(gbx%Reff > 1.e-8)) then |
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136 | reff_zero=.false. |
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137 | ! reff_zero == .false. |
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138 | ! and gbx%use_reff == .true. Reff use in radar and lidar |
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139 | ! and reff_zero == .false. Reff use in lidar and set to 0 for radar |
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140 | endif |
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141 | if ((.not. gbx%use_reff) .AND. (reff_zero)) then ! No Reff in radar. Default in lidar |
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142 | gbx%Reff = DEFAULT_LIDAR_REFF |
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143 | PRINT *, '---------- COSP WARNING ------------' |
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144 | PRINT *, '' |
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145 | PRINT *, 'Using default Reff in lidar simulations' |
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146 | PRINT *, '' |
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147 | PRINT *, '----------------------------------' |
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148 | endif |
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149 | |
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150 | ! Aerosols concentration and distribution parameters |
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151 | call cosp_check_input('conc_aero',gbx%conc_aero,min_val=0.0) |
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152 | ! Checks for CRM mode |
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153 | if (Ncolumns == 1) then |
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154 | if (gbx%use_precipitation_fluxes) then |
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155 | PRINT *, '---------- COSP ERROR ------------' |
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156 | PRINT *, '' |
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157 | PRINT *, 'Use of precipitation fluxes not supported in CRM mode (Ncolumns=1)' |
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158 | PRINT *, '' |
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159 | PRINT *, '----------------------------------' |
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160 | stop |
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161 | endif |
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162 | if ((maxval(gbx%dtau_c) > 0.0).or.(maxval(gbx%dem_c) > 0.0)) then |
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163 | PRINT *, '---------- COSP ERROR ------------' |
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164 | PRINT *, '' |
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165 | PRINT *, ' dtau_c > 0.0 or dem_c > 0.0. In CRM mode (Ncolumns=1), ' |
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166 | PRINT *, ' the optical depth (emmisivity) of all clouds must be ' |
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167 | PRINT *, ' passed through dtau_s (dem_s)' |
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168 | PRINT *, '' |
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169 | PRINT *, '----------------------------------' |
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170 | stop |
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171 | endif |
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172 | endif |
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173 | |
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174 | ! We base the seed in the decimal part of the surface pressure. |
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175 | allocate(seed(Npoints)) |
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176 | seed = int(gbx%psfc) ! This is to avoid division by zero when Npoints = 1 |
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177 | ! Roj Oct/2008 ... Note: seed value of 0 caused me some problems + I want to |
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178 | ! randomize for each call to COSP even when Npoints ==1 |
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179 | minp = minval(gbx%psfc) |
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180 | maxp = maxval(gbx%psfc) |
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181 | if (Npoints .gt. 1) seed=int((gbx%psfc-minp)/(maxp-minp)*100000) + 1 |
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182 | ! Below it's how it was done in the original implementation of the ISCCP simulator. |
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183 | ! The one above is better for offline data, when you may have packed data |
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184 | ! that subsamples the decimal fraction of the surface pressure. |
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185 | ! if (Npoints .gt. 1) seed=(gbx%psfc-int(gbx%psfc))*1000000 |
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186 | |
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187 | |
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188 | if (gbx%Npoints_it >= gbx%Npoints) then ! One iteration gbx%Npoints |
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189 | !#ifdef RTTOV |
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190 | ! call cosp_iter(overlap,seed,cfg,vgrid,gbx,sgx,sgradar,sglidar,isccp,misr,modis,rttov,stradar,stlidar) |
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191 | !#else |
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192 | call cosp_iter(overlap,seed,cfg,vgrid,gbx,sgx,sgradar,sglidar,isccp,misr,modis,stradar,stlidar) |
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193 | !#endif |
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194 | else ! Several iterations to save memory |
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195 | Niter = gbx%Npoints/gbx%Npoints_it ! Integer division |
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196 | if (Niter*gbx%Npoints_it < gbx%Npoints) Niter = Niter + 1 |
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197 | DO i=1,Niter |
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198 | i_first = (i-1)*gbx%Npoints_it + 1 |
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199 | i_last = i_first + gbx%Npoints_it - 1 |
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200 | i_last = min(i_last,gbx%Npoints) |
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201 | Ni = i_last - i_first + 1 |
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202 | if (i == 1) then |
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203 | ! Allocate types for all but last iteration |
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204 | call construct_cosp_gridbox(gbx%time,gbx%time_bnds,gbx%radar_freq,gbx%surface_radar,gbx%use_mie_tables, & |
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205 | gbx%use_gas_abs,gbx%do_ray,gbx%melt_lay,gbx%k2,Ni,Nlevels, & |
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206 | Ncolumns,N_HYDRO,gbx%Nprmts_max_hydro, & |
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207 | gbx%Naero,gbx%Nprmts_max_aero,Ni,gbx%lidar_ice_type,gbx%isccp_top_height, & |
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208 | gbx%isccp_top_height_direction,gbx%isccp_overlap,gbx%isccp_emsfc_lw, & |
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209 | gbx%use_precipitation_fluxes,gbx%use_reff, & |
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210 | gbx%plat,gbx%sat,gbx%inst,gbx%nchan,gbx%ZenAng, & |
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211 | gbx%Ichan(1:gbx%nchan),gbx%surfem(1:gbx%nchan), & |
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212 | gbx%co2,gbx%ch4,gbx%n2o,gbx%co, & |
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213 | gbx_it) |
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214 | call construct_cosp_vgrid(gbx_it,vgrid%Nlvgrid,vgrid%use_vgrid,vgrid%csat_vgrid,vgrid_it) |
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215 | call construct_cosp_subgrid(Ni, Ncolumns, Nlevels, sgx_it) |
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216 | call construct_cosp_sgradar(cfg,Ni,Ncolumns,Nlevels,N_HYDRO,sgradar_it) |
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217 | call construct_cosp_sglidar(cfg,Ni,Ncolumns,Nlevels,N_HYDRO,PARASOL_NREFL,sglidar_it) |
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218 | call construct_cosp_isccp(cfg,Ni,Ncolumns,Nlevels,isccp_it) |
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219 | call construct_cosp_modis(cfg, Ni, modis_it) |
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220 | call construct_cosp_misr(cfg,Ni,misr_it) |
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221 | !#ifdef RTTOV |
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222 | ! call construct_cosp_rttov(Ni,gbx%nchan,rttov_it) |
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223 | !#endif |
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224 | call construct_cosp_radarstats(cfg,Ni,Ncolumns,vgrid%Nlvgrid,N_HYDRO,stradar_it) |
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225 | call construct_cosp_lidarstats(cfg,Ni,Ncolumns,vgrid%Nlvgrid,N_HYDRO,PARASOL_NREFL,stlidar_it) |
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226 | elseif (i == Niter) then ! last iteration |
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227 | call free_cosp_gridbox(gbx_it,.true.) |
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228 | call free_cosp_subgrid(sgx_it) |
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229 | call free_cosp_vgrid(vgrid_it) |
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230 | call free_cosp_sgradar(sgradar_it) |
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231 | call free_cosp_sglidar(sglidar_it) |
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232 | call free_cosp_isccp(isccp_it) |
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233 | call free_cosp_modis(modis_it) |
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234 | call free_cosp_misr(misr_it) |
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235 | !#ifdef RTTOV |
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236 | ! call free_cosp_rttov(rttov_it) |
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237 | !#endif |
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238 | call free_cosp_radarstats(stradar_it) |
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239 | call free_cosp_lidarstats(stlidar_it) |
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240 | ! Allocate types for iterations |
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241 | call construct_cosp_gridbox(gbx%time,gbx%time_bnds,gbx%radar_freq,gbx%surface_radar,gbx%use_mie_tables, & |
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242 | gbx%use_gas_abs,gbx%do_ray,gbx%melt_lay,gbx%k2,Ni,Nlevels, & |
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243 | Ncolumns,N_HYDRO,gbx%Nprmts_max_hydro, & |
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244 | gbx%Naero,gbx%Nprmts_max_aero,Ni,gbx%lidar_ice_type,gbx%isccp_top_height, & |
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245 | gbx%isccp_top_height_direction,gbx%isccp_overlap,gbx%isccp_emsfc_lw, & |
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246 | gbx%use_precipitation_fluxes,gbx%use_reff, & |
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247 | gbx%plat,gbx%sat,gbx%inst,gbx%nchan,gbx%ZenAng, & |
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248 | gbx%Ichan(1:gbx%nchan),gbx%surfem(1:gbx%nchan), & |
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249 | gbx%co2,gbx%ch4,gbx%n2o,gbx%co, & |
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250 | gbx_it) |
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251 | ! --- Copy arrays without Npoints as dimension --- |
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252 | gbx_it%dist_prmts_hydro = gbx%dist_prmts_hydro |
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253 | gbx_it%dist_type_aero = gbx_it%dist_type_aero |
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254 | call construct_cosp_vgrid(gbx_it,vgrid%Nlvgrid,vgrid%use_vgrid,vgrid%csat_vgrid,vgrid_it) |
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255 | call construct_cosp_subgrid(Ni, Ncolumns, Nlevels, sgx_it) |
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256 | call construct_cosp_sgradar(cfg,Ni,Ncolumns,Nlevels,N_HYDRO,sgradar_it) |
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257 | call construct_cosp_sglidar(cfg,Ni,Ncolumns,Nlevels,N_HYDRO,PARASOL_NREFL,sglidar_it) |
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258 | call construct_cosp_isccp(cfg,Ni,Ncolumns,Nlevels,isccp_it) |
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259 | call construct_cosp_modis(cfg,Ni, modis_it) |
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260 | call construct_cosp_misr(cfg,Ni,misr_it) |
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261 | !#ifdef RTTOV |
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262 | ! call construct_cosp_rttov(Ni,gbx%nchan,rttov_it) |
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263 | !#endif |
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264 | call construct_cosp_radarstats(cfg,Ni,Ncolumns,vgrid%Nlvgrid,N_HYDRO,stradar_it) |
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265 | call construct_cosp_lidarstats(cfg,Ni,Ncolumns,vgrid%Nlvgrid,N_HYDRO,PARASOL_NREFL,stlidar_it) |
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266 | endif |
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267 | ! --- Copy sections of arrays with Npoints as dimension --- |
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268 | ix=(/i_first,i_last/) |
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269 | iy=(/1,Ni/) |
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270 | call cosp_gridbox_cpsection(ix,iy,gbx,gbx_it) |
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271 | ! These serve as initialisation of *_it types |
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272 | call cosp_subgrid_cpsection(ix,iy,sgx,sgx_it) |
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273 | if (cfg%Lradar_sim) call cosp_sgradar_cpsection(ix,iy,sgradar,sgradar_it) |
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274 | if (cfg%Llidar_sim) call cosp_sglidar_cpsection(ix,iy,sglidar,sglidar_it) |
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275 | if (cfg%Lisccp_sim) call cosp_isccp_cpsection(ix,iy,isccp,isccp_it) |
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276 | if (cfg%Lmodis_sim) call cosp_modis_cpsection(ix,iy,modis,modis_it) |
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277 | if (cfg%Lmisr_sim) call cosp_misr_cpsection(ix,iy,misr,misr_it) |
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278 | !#ifdef RTTOV |
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279 | ! if (cfg%Lrttov_sim) call cosp_rttov_cpsection(ix,iy,rttov,rttov_it) |
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280 | !#endif |
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281 | if (cfg%Lradar_sim) call cosp_radarstats_cpsection(ix,iy,stradar,stradar_it) |
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282 | if (cfg%Llidar_sim) call cosp_lidarstats_cpsection(ix,iy,stlidar,stlidar_it) |
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283 | !#ifdef RTTOV |
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284 | ! call cosp_iter(overlap,seed(ix(1):ix(2)),cfg,vgrid_it,gbx_it,sgx_it,sgradar_it, & |
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285 | ! sglidar_it,isccp_it,misr_it,modis_it,rttov_it,stradar_it,stlidar_it) |
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286 | !#else |
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287 | call cosp_iter(overlap,seed(ix(1):ix(2)),cfg,vgrid_it,gbx_it,sgx_it,sgradar_it, & |
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288 | sglidar_it,isccp_it,misr_it,modis_it,stradar_it,stlidar_it) |
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289 | !#endif |
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290 | ! --- Copy results to output structures --- |
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291 | ix=(/1,Ni/) |
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292 | iy=(/i_first,i_last/) |
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293 | call cosp_subgrid_cpsection(ix,iy,sgx_it,sgx) |
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294 | if (cfg%Lradar_sim) call cosp_sgradar_cpsection(ix,iy,sgradar_it,sgradar) |
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295 | if (cfg%Llidar_sim) call cosp_sglidar_cpsection(ix,iy,sglidar_it,sglidar) |
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296 | if (cfg%Lisccp_sim) call cosp_isccp_cpsection(ix,iy,isccp_it,isccp) |
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297 | if (cfg%Lmodis_sim) call cosp_modis_cpsection(ix,iy,modis_it,modis) |
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298 | if (cfg%Lmisr_sim) call cosp_misr_cpsection(ix,iy,misr_it,misr) |
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299 | !#ifdef RTTOV |
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300 | ! if (cfg%Lrttov_sim) call cosp_rttov_cpsection(ix,iy,rttov_it,rttov) |
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301 | !#endif |
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302 | if (cfg%Lradar_sim) call cosp_radarstats_cpsection(ix,iy,stradar_it,stradar) |
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303 | if (cfg%Llidar_sim) call cosp_lidarstats_cpsection(ix,iy,stlidar_it,stlidar) |
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304 | enddo |
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305 | ! Deallocate types |
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306 | call free_cosp_gridbox(gbx_it,.true.) |
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307 | call free_cosp_subgrid(sgx_it) |
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308 | call free_cosp_vgrid(vgrid_it) |
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309 | call free_cosp_sgradar(sgradar_it) |
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310 | call free_cosp_sglidar(sglidar_it) |
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311 | call free_cosp_isccp(isccp_it) |
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312 | call free_cosp_modis(modis_it) |
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313 | call free_cosp_misr(misr_it) |
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314 | !#ifdef RTTOV |
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315 | ! call free_cosp_rttov(rttov_it) |
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316 | !#endif |
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317 | call free_cosp_radarstats(stradar_it) |
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318 | call free_cosp_lidarstats(stlidar_it) |
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319 | endif |
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320 | deallocate(seed) |
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321 | |
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322 | |
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323 | END SUBROUTINE COSP |
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324 | |
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325 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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326 | !--------------------- SUBROUTINE COSP_ITER ---------------------- |
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327 | !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% |
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328 | !#ifdef RTTOV |
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329 | !SUBROUTINE COSP_ITER(overlap,seed,cfg,vgrid,gbx,sgx,sgradar,sglidar,isccp,misr,modis,rttov,stradar,stlidar) |
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330 | !#else |
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331 | SUBROUTINE COSP_ITER(overlap,seed,cfg,vgrid,gbx,sgx,sgradar,sglidar,isccp,misr,modis,stradar,stlidar) |
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332 | !#endif |
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333 | ! Arguments |
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334 | integer,intent(in) :: overlap ! overlap type in SCOPS: 1=max, 2=rand, 3=max/rand |
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335 | integer,dimension(:),intent(in) :: seed |
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336 | type(cosp_config),intent(in) :: cfg ! Configuration options |
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337 | type(cosp_vgrid),intent(in) :: vgrid ! Information on vertical grid of stats |
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338 | type(cosp_gridbox),intent(inout) :: gbx |
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339 | type(cosp_subgrid),intent(inout) :: sgx ! Subgrid info |
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340 | type(cosp_sgradar),intent(inout) :: sgradar ! Output from radar simulator |
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341 | type(cosp_sglidar),intent(inout) :: sglidar ! Output from lidar simulator |
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342 | type(cosp_isccp),intent(inout) :: isccp ! Output from ISCCP simulator |
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343 | type(cosp_misr),intent(inout) :: misr ! Output from MISR simulator |
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344 | type(cosp_modis),intent(inout) :: modis ! Output from MODIS simulator |
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345 | !#ifdef RTTOV |
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346 | ! type(cosp_rttov),intent(inout) :: rttov ! Output from RTTOV |
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347 | !#endif |
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348 | type(cosp_radarstats),intent(inout) :: stradar ! Summary statistics from radar simulator |
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349 | type(cosp_lidarstats),intent(inout) :: stlidar ! Summary statistics from lidar simulator |
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350 | |
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351 | ! Local variables |
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352 | integer :: Npoints ! Number of gridpoints |
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353 | integer :: Ncolumns ! Number of subcolumns |
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354 | integer :: Nlevels ! Number of levels |
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355 | integer :: Nhydro ! Number of hydrometeors |
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356 | integer :: i,j,k |
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357 | integer :: I_HYDRO |
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358 | real,dimension(:,:),pointer :: column_frac_out ! Array with one column of frac_out |
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359 | real,dimension(:,:),pointer :: column_prec_out ! Array with one column of prec_frac |
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360 | integer :: scops_debug=0 ! set to non-zero value to print out inputs for debugging in SCOPS |
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361 | real,dimension(:, :),allocatable :: cca_scops,ls_p_rate,cv_p_rate, & |
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362 | tca_scops ! Cloud cover in each model level (HORIZONTAL gridbox fraction) of total cloud. |
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363 | ! Levels are from TOA to SURFACE. (nPoints, nLev) |
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364 | real,dimension(:,:),allocatable :: frac_ls,prec_ls,frac_cv,prec_cv ! Cloud/Precipitation fraction in each model level |
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365 | ! Levels are from SURFACE to TOA |
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366 | real,dimension(:,:),allocatable :: rho ! (Npoints, Nlevels). Atmospheric density |
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367 | type(cosp_sghydro) :: sghydro ! Subgrid info for hydrometeors en each iteration |
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368 | |
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369 | |
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370 | !++++++++++ Dimensions ++++++++++++ |
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371 | Npoints = gbx%Npoints |
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372 | Ncolumns = gbx%Ncolumns |
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373 | Nlevels = gbx%Nlevels |
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374 | Nhydro = gbx%Nhydro |
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375 | |
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376 | !++++++++++ Climate/NWP mode ++++++++++ |
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377 | if (Ncolumns > 1) then |
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378 | !++++++++++ Subgrid sampling ++++++++++ |
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379 | ! Allocate arrays before calling SCOPS |
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380 | allocate(frac_ls(Npoints,Nlevels),frac_cv(Npoints,Nlevels),prec_ls(Npoints,Nlevels),prec_cv(Npoints,Nlevels)) |
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381 | allocate(tca_scops(Npoints,Nlevels),cca_scops(Npoints,Nlevels), & |
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382 | ls_p_rate(Npoints,Nlevels),cv_p_rate(Npoints,Nlevels)) |
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383 | ! Initialize to zero |
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384 | frac_ls=0.0 |
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385 | prec_ls=0.0 |
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386 | frac_cv=0.0 |
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387 | prec_cv=0.0 |
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388 | ! Cloud fractions for SCOPS from TOA to SFC |
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389 | tca_scops = gbx%tca(:,Nlevels:1:-1) |
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390 | cca_scops = gbx%cca(:,Nlevels:1:-1) |
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391 | |
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392 | ! Call to SCOPS |
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393 | ! strat and conv arrays are passed with levels from TOA to SURFACE. |
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394 | call scops(Npoints,Nlevels,Ncolumns,seed,tca_scops,cca_scops,overlap,sgx%frac_out,scops_debug) |
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395 | |
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396 | ! temporarily use prec_ls/cv to transfer information about precipitation flux into prec_scops |
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397 | if(gbx%use_precipitation_fluxes) then |
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398 | ls_p_rate(:,Nlevels:1:-1)=gbx%rain_ls(:,1:Nlevels)+gbx%snow_ls(:,1:Nlevels)+gbx%grpl_ls(:,1:Nlevels) |
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399 | cv_p_rate(:,Nlevels:1:-1)=gbx%rain_cv(:,1:Nlevels)+gbx%snow_cv(:,1:Nlevels) |
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400 | else |
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401 | ls_p_rate(:,Nlevels:1:-1)=gbx%mr_hydro(:,1:Nlevels,I_LSRAIN)+ & |
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402 | gbx%mr_hydro(:,1:Nlevels,I_LSSNOW)+ & |
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403 | gbx%mr_hydro(:,1:Nlevels,I_LSGRPL) |
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404 | cv_p_rate(:,Nlevels:1:-1)=gbx%mr_hydro(:,1:Nlevels,I_CVRAIN)+ & |
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405 | gbx%mr_hydro(:,1:Nlevels,I_CVSNOW) |
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406 | endif |
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407 | |
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408 | call prec_scops(Npoints,Nlevels,Ncolumns,ls_p_rate,cv_p_rate,sgx%frac_out,sgx%prec_frac) |
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409 | |
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410 | ! Precipitation fraction |
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411 | DO j=1,Npoints,1 |
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412 | DO k=1,Nlevels,1 |
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413 | DO i=1,Ncolumns,1 |
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414 | if (sgx%frac_out (j,i,Nlevels+1-k) == I_LSC) frac_ls(j,k)=frac_ls(j,k)+1. |
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415 | if (sgx%frac_out (j,i,Nlevels+1-k) == I_CVC) frac_cv(j,k)=frac_cv(j,k)+1. |
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416 | if (sgx%prec_frac(j,i,Nlevels+1-k) .eq. 1) prec_ls(j,k)=prec_ls(j,k)+1. |
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417 | if (sgx%prec_frac(j,i,Nlevels+1-k) .eq. 2) prec_cv(j,k)=prec_cv(j,k)+1. |
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418 | if (sgx%prec_frac(j,i,Nlevels+1-k) .eq. 3) then |
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419 | prec_cv(j,k)=prec_cv(j,k)+1. |
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420 | prec_ls(j,k)=prec_ls(j,k)+1. |
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421 | endif |
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422 | enddo !i |
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423 | frac_ls(j,k)=frac_ls(j,k)/Ncolumns |
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424 | frac_cv(j,k)=frac_cv(j,k)/Ncolumns |
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425 | prec_ls(j,k)=prec_ls(j,k)/Ncolumns |
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426 | prec_cv(j,k)=prec_cv(j,k)/Ncolumns |
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427 | enddo !k |
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428 | enddo !j |
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429 | |
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430 | ! Levels from SURFACE to TOA. |
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431 | if (Npoints*Ncolumns*Nlevels < 10000) then |
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432 | sgx%frac_out(1:Npoints,:,1:Nlevels) = sgx%frac_out(1:Npoints,:,Nlevels:1:-1) |
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433 | sgx%prec_frac(1:Npoints,:,1:Nlevels) = sgx%prec_frac(1:Npoints,:,Nlevels:1:-1) |
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434 | else |
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435 | ! This is done within a loop (unvectorized) over nPoints to save memory |
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436 | DO j=1,Npoints |
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437 | sgx%frac_out(j,:,1:Nlevels) = sgx%frac_out(j,:,Nlevels:1:-1) |
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438 | sgx%prec_frac(j,:,1:Nlevels) = sgx%prec_frac(j,:,Nlevels:1:-1) |
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439 | enddo |
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440 | endif |
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441 | |
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442 | ! Deallocate arrays that will no longer be used |
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443 | deallocate(tca_scops,cca_scops,ls_p_rate,cv_p_rate) |
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444 | |
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445 | ! Populate the subgrid arrays |
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446 | call construct_cosp_sghydro(Npoints,Ncolumns,Nlevels,Nhydro,sghydro) |
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447 | DO k=1,Ncolumns |
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448 | !--------- Mixing ratios for clouds and Reff for Clouds and precip ------- |
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449 | column_frac_out => sgx%frac_out(:,k,:) |
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450 | where (column_frac_out == I_LSC) !+++++++++++ LS clouds ++++++++ |
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451 | sghydro%mr_hydro(:,k,:,I_LSCLIQ) = gbx%mr_hydro(:,:,I_LSCLIQ) |
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452 | sghydro%mr_hydro(:,k,:,I_LSCICE) = gbx%mr_hydro(:,:,I_LSCICE) |
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453 | |
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454 | sghydro%Reff(:,k,:,I_LSCLIQ) = gbx%Reff(:,:,I_LSCLIQ) |
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455 | sghydro%Reff(:,k,:,I_LSCICE) = gbx%Reff(:,:,I_LSCICE) |
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456 | |
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457 | sghydro%Np(:,k,:,I_LSCLIQ) = gbx%Np(:,:,I_LSCLIQ) |
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458 | sghydro%Np(:,k,:,I_LSCICE) = gbx%Np(:,:,I_LSCICE) |
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459 | |
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460 | elsewhere (column_frac_out == I_CVC) !+++++++++++ CONV clouds ++++++++ |
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461 | sghydro%mr_hydro(:,k,:,I_CVCLIQ) = gbx%mr_hydro(:,:,I_CVCLIQ) |
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462 | sghydro%mr_hydro(:,k,:,I_CVCICE) = gbx%mr_hydro(:,:,I_CVCICE) |
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463 | |
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464 | sghydro%Reff(:,k,:,I_CVCLIQ) = gbx%Reff(:,:,I_CVCLIQ) |
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465 | sghydro%Reff(:,k,:,I_CVCICE) = gbx%Reff(:,:,I_CVCICE) |
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466 | |
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467 | sghydro%Np(:,k,:,I_CVCLIQ) = gbx%Np(:,:,I_CVCLIQ) |
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468 | sghydro%Np(:,k,:,I_CVCICE) = gbx%Np(:,:,I_CVCICE) |
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469 | |
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470 | end where |
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471 | column_prec_out => sgx%prec_frac(:,k,:) |
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472 | where ((column_prec_out == 1) .or. (column_prec_out == 3) ) !++++ LS precip ++++ |
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473 | sghydro%Reff(:,k,:,I_LSRAIN) = gbx%Reff(:,:,I_LSRAIN) |
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474 | sghydro%Reff(:,k,:,I_LSSNOW) = gbx%Reff(:,:,I_LSSNOW) |
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475 | sghydro%Reff(:,k,:,I_LSGRPL) = gbx%Reff(:,:,I_LSGRPL) |
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476 | |
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477 | sghydro%Np(:,k,:,I_LSRAIN) = gbx%Np(:,:,I_LSRAIN) |
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478 | sghydro%Np(:,k,:,I_LSSNOW) = gbx%Np(:,:,I_LSSNOW) |
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479 | sghydro%Np(:,k,:,I_LSGRPL) = gbx%Np(:,:,I_LSGRPL) |
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480 | elsewhere ((column_prec_out == 2) .or. (column_prec_out == 3)) !++++ CONV precip ++++ |
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481 | sghydro%Reff(:,k,:,I_CVRAIN) = gbx%Reff(:,:,I_CVRAIN) |
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482 | sghydro%Reff(:,k,:,I_CVSNOW) = gbx%Reff(:,:,I_CVSNOW) |
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483 | |
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484 | sghydro%Np(:,k,:,I_CVRAIN) = gbx%Np(:,:,I_CVRAIN) |
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485 | sghydro%Np(:,k,:,I_CVSNOW) = gbx%Np(:,:,I_CVSNOW) |
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486 | end where |
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487 | !--------- Precip ------- |
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488 | if (.not. gbx%use_precipitation_fluxes) then |
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489 | where (column_frac_out == I_LSC) !+++++++++++ LS Precipitation ++++++++ |
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490 | sghydro%mr_hydro(:,k,:,I_LSRAIN) = gbx%mr_hydro(:,:,I_LSRAIN) |
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491 | sghydro%mr_hydro(:,k,:,I_LSSNOW) = gbx%mr_hydro(:,:,I_LSSNOW) |
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492 | sghydro%mr_hydro(:,k,:,I_LSGRPL) = gbx%mr_hydro(:,:,I_LSGRPL) |
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493 | elsewhere (column_frac_out == I_CVC) !+++++++++++ CONV Precipitation ++++++++ |
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494 | sghydro%mr_hydro(:,k,:,I_CVRAIN) = gbx%mr_hydro(:,:,I_CVRAIN) |
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495 | sghydro%mr_hydro(:,k,:,I_CVSNOW) = gbx%mr_hydro(:,:,I_CVSNOW) |
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496 | end where |
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497 | endif |
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498 | enddo |
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499 | ! convert the mixing ratio and precipitation flux from gridbox mean to the fraction-based values |
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500 | DO k=1,Nlevels |
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501 | DO j=1,Npoints |
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502 | !--------- Clouds ------- |
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503 | if (frac_ls(j,k) .ne. 0.) then |
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504 | sghydro%mr_hydro(j,:,k,I_LSCLIQ) = sghydro%mr_hydro(j,:,k,I_LSCLIQ)/frac_ls(j,k) |
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505 | sghydro%mr_hydro(j,:,k,I_LSCICE) = sghydro%mr_hydro(j,:,k,I_LSCICE)/frac_ls(j,k) |
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506 | endif |
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507 | if (frac_cv(j,k) .ne. 0.) then |
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508 | sghydro%mr_hydro(j,:,k,I_CVCLIQ) = sghydro%mr_hydro(j,:,k,I_CVCLIQ)/frac_cv(j,k) |
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509 | sghydro%mr_hydro(j,:,k,I_CVCICE) = sghydro%mr_hydro(j,:,k,I_CVCICE)/frac_cv(j,k) |
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510 | endif |
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511 | !--------- Precip ------- |
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512 | if (gbx%use_precipitation_fluxes) then |
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513 | if (prec_ls(j,k) .ne. 0.) then |
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514 | gbx%rain_ls(j,k) = gbx%rain_ls(j,k)/prec_ls(j,k) |
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515 | gbx%snow_ls(j,k) = gbx%snow_ls(j,k)/prec_ls(j,k) |
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516 | gbx%grpl_ls(j,k) = gbx%grpl_ls(j,k)/prec_ls(j,k) |
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517 | endif |
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518 | if (prec_cv(j,k) .ne. 0.) then |
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519 | gbx%rain_cv(j,k) = gbx%rain_cv(j,k)/prec_cv(j,k) |
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520 | gbx%snow_cv(j,k) = gbx%snow_cv(j,k)/prec_cv(j,k) |
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521 | endif |
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522 | else |
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523 | if (prec_ls(j,k) .ne. 0.) then |
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524 | sghydro%mr_hydro(j,:,k,I_LSRAIN) = sghydro%mr_hydro(j,:,k,I_LSRAIN)/prec_ls(j,k) |
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525 | sghydro%mr_hydro(j,:,k,I_LSSNOW) = sghydro%mr_hydro(j,:,k,I_LSSNOW)/prec_ls(j,k) |
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526 | sghydro%mr_hydro(j,:,k,I_LSGRPL) = sghydro%mr_hydro(j,:,k,I_LSGRPL)/prec_ls(j,k) |
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527 | endif |
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528 | if (prec_cv(j,k) .ne. 0.) then |
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529 | sghydro%mr_hydro(j,:,k,I_CVRAIN) = sghydro%mr_hydro(j,:,k,I_CVRAIN)/prec_cv(j,k) |
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530 | sghydro%mr_hydro(j,:,k,I_CVSNOW) = sghydro%mr_hydro(j,:,k,I_CVSNOW)/prec_cv(j,k) |
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531 | endif |
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532 | endif |
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533 | enddo !k |
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534 | enddo !j |
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535 | deallocate(frac_ls,prec_ls,frac_cv,prec_cv) |
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536 | |
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537 | if (gbx%use_precipitation_fluxes) then |
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538 | |
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539 | #ifdef MMF_V3p5_TWO_MOMENT |
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540 | |
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541 | write(*,*) 'Precipitation Flux to Mixing Ratio conversion not (yet?) supported ', & |
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542 | 'for MMF3.5 Two Moment Microphysics' |
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543 | stop |
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544 | #else |
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545 | ! Density |
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546 | allocate(rho(Npoints,Nlevels)) |
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547 | I_HYDRO = I_LSRAIN |
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548 | call cosp_precip_mxratio(Npoints,Nlevels,Ncolumns,gbx%p,gbx%T,sgx%prec_frac,1., & |
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549 | n_ax(I_HYDRO),n_bx(I_HYDRO),alpha_x(I_HYDRO),c_x(I_HYDRO),d_x(I_HYDRO), & |
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550 | g_x(I_HYDRO),a_x(I_HYDRO),b_x(I_HYDRO), & |
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551 | gamma_1(I_HYDRO),gamma_2(I_HYDRO),gamma_3(I_HYDRO),gamma_4(I_HYDRO), & |
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552 | gbx%rain_ls,sghydro%mr_hydro(:,:,:,I_HYDRO),sghydro%Reff(:,:,:,I_HYDRO)) |
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553 | I_HYDRO = I_LSSNOW |
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554 | call cosp_precip_mxratio(Npoints,Nlevels,Ncolumns,gbx%p,gbx%T,sgx%prec_frac,1., & |
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555 | n_ax(I_HYDRO),n_bx(I_HYDRO),alpha_x(I_HYDRO),c_x(I_HYDRO),d_x(I_HYDRO), & |
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556 | g_x(I_HYDRO),a_x(I_HYDRO),b_x(I_HYDRO), & |
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557 | gamma_1(I_HYDRO),gamma_2(I_HYDRO),gamma_3(I_HYDRO),gamma_4(I_HYDRO), & |
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558 | gbx%snow_ls,sghydro%mr_hydro(:,:,:,I_HYDRO),sghydro%Reff(:,:,:,I_HYDRO)) |
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559 | I_HYDRO = I_CVRAIN |
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560 | call cosp_precip_mxratio(Npoints,Nlevels,Ncolumns,gbx%p,gbx%T,sgx%prec_frac,2., & |
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561 | n_ax(I_HYDRO),n_bx(I_HYDRO),alpha_x(I_HYDRO),c_x(I_HYDRO),d_x(I_HYDRO), & |
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562 | g_x(I_HYDRO),a_x(I_HYDRO),b_x(I_HYDRO), & |
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563 | gamma_1(I_HYDRO),gamma_2(I_HYDRO),gamma_3(I_HYDRO),gamma_4(I_HYDRO), & |
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564 | gbx%rain_cv,sghydro%mr_hydro(:,:,:,I_HYDRO),sghydro%Reff(:,:,:,I_HYDRO)) |
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565 | I_HYDRO = I_CVSNOW |
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566 | call cosp_precip_mxratio(Npoints,Nlevels,Ncolumns,gbx%p,gbx%T,sgx%prec_frac,2., & |
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567 | n_ax(I_HYDRO),n_bx(I_HYDRO),alpha_x(I_HYDRO),c_x(I_HYDRO),d_x(I_HYDRO), & |
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568 | g_x(I_HYDRO),a_x(I_HYDRO),b_x(I_HYDRO), & |
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569 | gamma_1(I_HYDRO),gamma_2(I_HYDRO),gamma_3(I_HYDRO),gamma_4(I_HYDRO), & |
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570 | gbx%snow_cv,sghydro%mr_hydro(:,:,:,I_HYDRO),sghydro%Reff(:,:,:,I_HYDRO)) |
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571 | I_HYDRO = I_LSGRPL |
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572 | call cosp_precip_mxratio(Npoints,Nlevels,Ncolumns,gbx%p,gbx%T,sgx%prec_frac,1., & |
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573 | n_ax(I_HYDRO),n_bx(I_HYDRO),alpha_x(I_HYDRO),c_x(I_HYDRO),d_x(I_HYDRO), & |
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574 | g_x(I_HYDRO),a_x(I_HYDRO),b_x(I_HYDRO), & |
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575 | gamma_1(I_HYDRO),gamma_2(I_HYDRO),gamma_3(I_HYDRO),gamma_4(I_HYDRO), & |
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576 | gbx%grpl_ls,sghydro%mr_hydro(:,:,:,I_HYDRO),sghydro%Reff(:,:,:,I_HYDRO)) |
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577 | if(allocated(rho)) deallocate(rho) |
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578 | #endif |
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579 | |
---|
580 | endif |
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581 | !++++++++++ CRM mode ++++++++++ |
---|
582 | else |
---|
583 | call construct_cosp_sghydro(Npoints,Ncolumns,Nlevels,Nhydro,sghydro) |
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584 | sghydro%mr_hydro(:,1,:,:) = gbx%mr_hydro |
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585 | sghydro%Reff(:,1,:,:) = gbx%Reff |
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586 | sghydro%Np(:,1,:,:) = gbx%Np ! added by Roj with Quickbeam V3.0 |
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587 | |
---|
588 | !--------- Clouds ------- |
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589 | where ((gbx%dtau_s > 0.0)) |
---|
590 | sgx%frac_out(:,1,:) = 1 ! Subgrid cloud array. Dimensions (Npoints,Ncolumns,Nlevels) |
---|
591 | endwhere |
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592 | endif ! Ncolumns > 1 |
---|
593 | |
---|
594 | !++++++++++ Simulator ++++++++++ |
---|
595 | !#ifdef RTTOV |
---|
596 | ! call cosp_simulator(gbx,sgx,sghydro,cfg,vgrid,sgradar,sglidar,isccp,misr,modis,rttov,stradar,stlidar) |
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597 | !#else |
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598 | call cosp_simulator(gbx,sgx,sghydro,cfg,vgrid,sgradar,sglidar,isccp,misr,modis,stradar,stlidar) |
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599 | !#endif |
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600 | |
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601 | ! Deallocate subgrid arrays |
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602 | call free_cosp_sghydro(sghydro) |
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603 | END SUBROUTINE COSP_ITER |
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604 | |
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605 | END MODULE MOD_COSP |
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