! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Copyright (c) 2015, Regents of the University of Colorado ! All rights reserved. ! ! Redistribution and use in source and binary forms, with or without modification, are ! permitted provided that the following conditions are met: ! ! 1. Redistributions of source code must retain the above copyright notice, this list of ! conditions and the following disclaimer. ! ! 2. Redistributions in binary form must reproduce the above copyright notice, this list ! of conditions and the following disclaimer in the documentation and/or other ! materials provided with the distribution. ! ! 3. Neither the name of the copyright holder nor the names of its contributors may be ! used to endorse or promote products derived from this software without specific prior ! written permission. ! ! THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY ! EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF ! MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL ! THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, ! SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT ! OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS ! INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT ! LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE ! OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. ! ! History: ! May 2015- D. Swales - Original version ! ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% MODULE MOD_COSP USE COSP_KINDS, ONLY: wp USE MOD_COSP_CONFIG, ONLY: R_UNDEF,PARASOL_NREFL,LIDAR_NCAT,SR_BINS, & N_HYDRO,RTTOV_MAX_CHANNELS,numMISRHgtBins, & DBZE_BINS,LIDAR_NTEMP,calipso_histBsct, & use_vgrid,Nlvgrid,vgrid_zu,vgrid_zl,vgrid_z, & numMODISTauBins,numMODISPresBins, & numMODISReffIceBins,numMODISReffLiqBins, & numISCCPTauBins,numISCCPPresBins,numMISRTauBins,& ntau,modis_histTau,tau_binBounds, & modis_histTauEdges,tau_binEdges, & modis_histTauCenters,tau_binCenters USE MOD_COSP_MODIS_INTERFACE, ONLY: cosp_modis_init, modis_IN ! USE MOD_COSP_RTTOV_INTERFACE, ONLY: cosp_rttov_init, rttov_IN USE MOD_COSP_MISR_INTERFACE, ONLY: cosp_misr_init, misr_IN USE MOD_COSP_ISCCP_INTERFACE, ONLY: cosp_isccp_init, isccp_IN USE MOD_COSP_CALIPSO_INTERFACE, ONLY: cosp_calipso_init, calipso_IN USE MOD_COSP_PARASOL_INTERFACE, ONLY: cosp_parasol_init, parasol_in USE MOD_COSP_CLOUDSAT_INTERFACE, ONLY: cosp_cloudsat_init, cloudsat_IN USE quickbeam, ONLY: quickbeam_subcolumn, quickbeam_column, radar_cfg USE MOD_ICARUS, ONLY: icarus_subcolumn, icarus_column USE MOD_MISR_SIMULATOR, ONLY: misr_subcolumn, misr_column USE MOD_LIDAR_SIMULATOR, ONLY: lidar_subcolumn, lidar_column USE MOD_MODIS_SIM, ONLY: modis_subcolumn, modis_column USE MOD_PARASOL, ONLY: parasol_subcolumn, parasol_column ! use mod_cosp_rttov, ONLY: rttov_column USE MOD_COSP_STATS, ONLY: COSP_LIDAR_ONLY_CLOUD,COSP_CHANGE_VERTICAL_GRID IMPLICIT NONE logical :: linitialization ! Initialization flag ! ###################################################################################### ! TYPE cosp_column_inputs ! ###################################################################################### type cosp_column_inputs integer :: & Npoints, & ! Number of gridpoints. Ncolumns, & ! Number of columns. Nlevels ! Number of levels. integer,allocatable,dimension(:) :: & sunlit ! Sunlit flag (0-1) real(wp),allocatable,dimension(:,:) :: & at, & ! Temperature (K) pfull, & ! Pressure (Pa) phalf, & ! Pressure at half-levels (Pa) qv, & ! Specific humidity (kg/kg) hgt_matrix, & ! Height of hydrometeors (km) hgt_matrix_half ! Height of hydrometeors at half levels (km) real(wp),allocatable,dimension(:) :: & land, & ! Land/Sea mask (0-1) skt ! Surface temperature (K) ! Fields used ONLY by RTTOV integer :: & month ! Month for surface emissivty atlas (1-12) real(wp) :: & zenang, & ! Satellite zenith angle for RTTOV (deg) co2, & ! CO2 (kg/kg) ch4, & ! Methane (kg/kg) n2o, & ! N2O (kg/kg) co ! CO (kg/kg) real(wp),allocatable,dimension(:) :: & emis_sfc, & ! Surface emissivity (1) u_sfc, & ! Surface u-wind (m/s) v_sfc, & ! Surface v-wind (m/s) seaice, & ! Sea-ice fraction (0-1) lat, & ! Latitude (deg) lon ! Longitude (deg) real(wp),allocatable,dimension(:,:) :: & o3, & ! Ozone (kg/kg) tca, & ! Total column cloud fraction (0-1) cloudIce, & ! Cloud ice water mixing ratio (kg/kg) cloudLiq, & ! Cloud liquid water mixing ratio (kg/kg) fl_rain, & ! Precipitation (rain) flux (kg/m2/s) fl_snow ! Precipitation (snow) flux (kg/m2/s) end type cosp_column_inputs ! ###################################################################################### ! TYPE cosp_optical_inputs ! ###################################################################################### type cosp_optical_inputs integer :: & Npoints, & ! Number of gridpoints. Ncolumns, & ! Number of columns. Nlevels, & ! Number of levels. Npart, & ! Number of cloud meteors for LIDAR simulator. Nrefl ! Number of reflectances for PARASOL simulator real(wp) :: & emsfc_lw ! 11 micron surface emissivity real(wp),allocatable,dimension(:,:,:) :: & frac_out, & ! Cloud fraction tau_067, & ! Optical depth fracLiq, & ! Cloud fraction emiss_11, & ! Emissivity asym, & ! Assymetry parameter ss_alb, & ! Single-scattering albedo betatot, & ! Backscatter coefficient for polarized optics (total) betatot_ice, & ! Backscatter coefficient for polarized optics (ice) betatot_liq, & ! Backscatter coefficient for polarized optics (liquid) tautot, & ! Optical thickess integrated from top (total) tautot_ice, & ! Optical thickess integrated from top (ice) tautot_liq, & ! Optical thickess integrated from top (liquid) z_vol_cloudsat, & ! Effective reflectivity factor (mm^6/m^3) kr_vol_cloudsat, & ! Attenuation coefficient hydro (dB/km) g_vol_cloudsat ! Attenuation coefficient gases (dB/km) real(wp),allocatable,dimension(:,:) :: & beta_mol, & ! Molecular backscatter coefficient tau_mol, & ! Molecular optical depth tautot_S_liq, & ! Liquid water optical thickness, from TOA to SFC tautot_S_ice ! Ice water optical thickness, from TOA to SFC type(radar_cfg) :: & rcfg_cloudsat ! Radar comfiguration information (CLOUDSAT) end type cosp_optical_inputs ! ###################################################################################### ! TYPE cosp_outputs ! ###################################################################################### type cosp_outputs ! CALIPSO outputs real(wp),dimension(:,:,:),pointer :: & calipso_betaperp_tot => null(), & ! Total backscattered signal calipso_beta_tot => null(), & ! Total backscattered signal calipso_tau_tot => null(), & ! Optical thickness integrated from top to level z calipso_lidarcldphase => null(), & ! 3D "lidar" phase cloud fraction calipso_cldlayerphase => null(), & ! low, mid, high-level lidar phase cloud cover calipso_lidarcldtmp => null(), & ! 3D "lidar" phase cloud temperature calipso_cfad_sr => null() ! CFAD of scattering ratio real(wp), dimension(:,:),pointer :: & calipso_lidarcld => null(), & ! 3D "lidar" cloud fraction calipso_cldlayer => null(), & ! low, mid, high-level, total lidar cloud cover calipso_beta_mol => null(), & ! Molecular backscatter calipso_temp_tot => null() real(wp), dimension(:),pointer :: & calipso_srbval => null() ! SR bins in cfad_sr ! PARASOL outputs real(wp),dimension(:,:,:),pointer :: & parasolPix_refl => null() ! PARASOL reflectances (subcolumn) real(wp),dimension(:,:),pointer :: & parasolGrid_refl => null() ! PARASOOL reflectances (column) ! CLOUDSAT outputs real(wp),dimension(:,:,:),pointer :: & cloudsat_Ze_tot => null(), & ! Effective reflectivity factor (Npoints,Ncolumns,Nlevels) cloudsat_cfad_ze => null() ! Ze CFAD(Npoints,dBZe_bins,Nlevels) real(wp), dimension(:,:),pointer :: & lidar_only_freq_cloud => null() ! (Npoints,Nlevels) real(wp),dimension(:),pointer :: & radar_lidar_tcc => null() ! Radar&lidar total cloud amount, grid-box scale (Npoints) ! ISCCP outputs real(wp),dimension(:),pointer :: & isccp_totalcldarea => null(), & ! The fraction of model grid box columns with cloud ! somewhere in them. (%) isccp_meantb => null(), & ! Mean all-sky 10.5 micron brightness temperature. (K) isccp_meantbclr => null(), & ! Mean clear-sky 10.5 micron brightness temperature. (K) isccp_meanptop => null(), & ! Mean cloud top pressure (mb). isccp_meantaucld => null(), & ! Mean optical thickness. (1) isccp_meanalbedocld => null() ! Mean cloud albedo. (1) real(wp),dimension(:,:),pointer ::& isccp_boxtau => null(), & ! Optical thickness in each column. (1) isccp_boxptop => null() ! Cloud top pressure in each column. (mb) real(wp),dimension(:,:,:),pointer :: & isccp_fq => null() ! The fraction of the model grid box covered by each of ! the 49 ISCCP D level cloud types. (%) ! MISR outptus real(wp),dimension(:,:,:),pointer :: & ! misr_fq => null() ! Fraction of the model grid box covered by each of the MISR ! cloud types real(wp),dimension(:,:),pointer :: & ! misr_dist_model_layertops => null() ! real(wp),dimension(:),pointer :: & ! misr_meanztop => null(), & ! Mean MISR cloud top height misr_cldarea => null() ! Mean MISR cloud cover area ! MODIS outptus real(wp),pointer,dimension(:) :: & ! modis_Cloud_Fraction_Total_Mean => null(), & ! L3 MODIS retrieved cloud fraction (total) modis_Cloud_Fraction_Water_Mean => null(), & ! L3 MODIS retrieved cloud fraction (liq) modis_Cloud_Fraction_Ice_Mean => null(), & ! L3 MODIS retrieved cloud fraction (ice) modis_Cloud_Fraction_High_Mean => null(), & ! L3 MODIS retrieved cloud fraction (high) modis_Cloud_Fraction_Mid_Mean => null(), & ! L3 MODIS retrieved cloud fraction (middle) modis_Cloud_Fraction_Low_Mean => null(), & ! L3 MODIS retrieved cloud fraction (low ) modis_Optical_Thickness_Total_Mean => null(), & ! L3 MODIS retrieved optical thickness (tot) modis_Optical_Thickness_Water_Mean => null(), & ! L3 MODIS retrieved optical thickness (liq) modis_Optical_Thickness_Ice_Mean => null(), & ! L3 MODIS retrieved optical thickness (ice) modis_Optical_Thickness_Total_LogMean => null(), & ! L3 MODIS retrieved log10 optical thickness modis_Optical_Thickness_Water_LogMean => null(), & ! L3 MODIS retrieved log10 optical thickness modis_Optical_Thickness_Ice_LogMean => null(), & ! L3 MODIS retrieved log10 optical thickness modis_Cloud_Particle_Size_Water_Mean => null(), & ! L3 MODIS retrieved particle size (liquid) modis_Cloud_Particle_Size_Ice_Mean => null(), & ! L3 MODIS retrieved particle size (ice) modis_Cloud_Top_Pressure_Total_Mean => null(), & ! L3 MODIS retrieved cloud top pressure modis_Liquid_Water_Path_Mean => null(), & ! L3 MODIS retrieved liquid water path modis_Ice_Water_Path_Mean => null() ! L3 MODIS retrieved ice water path real(wp),pointer,dimension(:,:,:) :: & modis_Optical_Thickness_vs_Cloud_Top_Pressure => null(), & ! Tau/Pressure joint histogram modis_Optical_Thickness_vs_ReffICE => null(), & ! Tau/ReffICE joint histogram modis_Optical_Thickness_vs_ReffLIQ => null() ! Tau/ReffLIQ joint histogram ! RTTOV outputs real(wp),pointer :: & rttov_tbs(:,:) => null() ! Brightness Temperature end type cosp_outputs CONTAINS ! ###################################################################################### ! FUNCTION cosp_simulator ! ###################################################################################### function COSP_SIMULATOR(cospIN,cospgridIN,cospOUT,start_idx,stop_idx,debug) type(cosp_optical_inputs),intent(in),target :: cospIN ! Optical inputs to COSP simulator type(cosp_column_inputs), intent(in),target :: cospgridIN ! Host model inputs to COSP ! Inputs into the simulators type(isccp_IN) :: isccpIN ! Input to the ISCCP simulator type(misr_IN) :: misrIN ! Input to the LIDAR simulator type(calipso_IN) :: calipsoIN ! Input to the LIDAR simulator type(parasol_IN) :: parasolIN ! Input to the PARASOL simulator type(cloudsat_IN) :: cloudsatIN ! Input to the CLOUDSAT radar simulator type(modis_IN) :: modisIN ! Input to the MODIS simulator ! type(rttov_IN) :: rttovIN ! Input to the RTTOV simulator integer,optional :: start_idx,stop_idx logical,optional :: debug ! Outputs from the simulators (nested simulator output structure) type(cosp_outputs), intent(inout) :: cospOUT character(len=256),dimension(100) :: cosp_simulator ! Local variables integer :: & i,icol,ij,ik,nError integer,target :: & Npoints logical :: & Lisccp_subcolumn, & ! On/Off switch for subcolumn ISCCP simulator Lmisr_subcolumn, & ! On/Off switch for subcolumn MISR simulator Lcalipso_subcolumn, & ! On/Off switch for subcolumn CALIPSO simulator Lparasol_subcolumn, & ! On/Off switch for subcolumn PARASOL simulator Lcloudsat_subcolumn, & ! On/Off switch for subcolumn CLOUDSAT simulator Lmodis_subcolumn, & ! On/Off switch for subcolumn MODIS simulator Lrttov_subcolumn, & ! On/Off switch for subcolumn RTTOV simulator Lisccp_column, & ! On/Off switch for column ISCCP simulator Lmisr_column, & ! On/Off switch for column MISR simulator Lcalipso_column, & ! On/Off switch for column CALIPSO simulator Lparasol_column, & ! On/Off switch for column PARASOL simulator Lcloudsat_column, & ! On/Off switch for column CLOUDSAT simulator Lmodis_column, & ! On/Off switch for column MODIS simulator Lrttov_column, & ! On/Off switch for column RTTOV simulator (not used) Lradar_lidar_tcc, & ! On/Off switch from joint Calipso/Cloudsat product Llidar_only_freq_cloud ! On/Off switch from joint Calipso/Cloudsat product logical :: & ok_lidar_cfad = .false., & lrttov_cleanUp = .false. integer, dimension(:,:),allocatable :: & modisRetrievedPhase,isccpLEVMATCH real(wp), dimension(:), allocatable :: & modisCfTotal,modisCfLiquid,modisMeanIceWaterPath, isccp_meantbclr, & modisCfIce, modisCfHigh, modisCfMid, modisCfLow,modisMeanTauTotal, & modisMeanTauLiquid, modisMeanTauIce, modisMeanLogTauTotal, & modisMeanLogTauLiquid, modisMeanLogTauIce, modisMeanSizeLiquid, & modisMeanSizeIce, modisMeanCloudTopPressure, modisMeanLiquidWaterPath, & radar_lidar_tcc REAL(WP), dimension(:,:),allocatable :: & modisRetrievedCloudTopPressure,modisRetrievedTau,modisRetrievedSize, & misr_boxtau,misr_boxztop,misr_dist_model_layertops,isccp_boxtau, & isccp_boxttop,isccp_boxptop,calipso_beta_mol,lidar_only_freq_cloud REAL(WP), dimension(:,:,:),allocatable :: & modisJointHistogram,modisJointHistogramIce,modisJointHistogramLiq, & calipso_beta_tot,calipso_betaperp_tot, cloudsatDBZe,parasolPix_refl real(wp),dimension(:),allocatable,target :: & out1D_1,out1D_2,out1D_3,out1D_4,out1D_5,out1D_6 real(wp),dimension(:,:,:),allocatable :: & betamol_in,betamolFlip,pnormFlip,ze_totFlip ! Initialize error reporting for output cosp_simulator(:)='' !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 1) Determine if using full inputs or subset !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (present(start_idx) .and. present(stop_idx)) then ij=start_idx ik=stop_idx else ij=1 ik=cospIN%Npoints endif Npoints = ik-ij+1 !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 2a) Determine which simulators to run and which statistics to compute ! - If any of the subcolumn fields are allocated, then run the subcolumn simulators. ! - If any of the column fields are allocated, then compute the statistics for that ! simulator, but only save the requested fields. !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Start with all simulators and joint-diagnostics off Lisccp_subcolumn = .false. Lmisr_subcolumn = .false. Lcalipso_subcolumn = .false. Lparasol_subcolumn = .false. Lcloudsat_subcolumn = .false. Lmodis_subcolumn = .false. Lrttov_subcolumn = .false. Lisccp_column = .false. Lmisr_column = .false. Lcalipso_column = .false. Lparasol_column = .false. Lcloudsat_column = .false. Lmodis_column = .false. Lrttov_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. ! CLOUDSAT subcolumn if (associated(cospOUT%cloudsat_Ze_tot)) Lcloudsat_subcolumn = .true. ! MODIS subcolumn if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Total_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Ice_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_High_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Mid_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Low_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Total_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Water_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Ice_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Total_LogMean) .or. & associated(cospOUT%modis_Optical_Thickness_Water_LogMean) .or. & associated(cospOUT%modis_Optical_Thickness_Ice_LogMean) .or. & associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean) .or. & associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean) .or. & associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean) .or. & associated(cospOUT%modis_Liquid_Water_Path_Mean) .or. & associated(cospOUT%modis_Ice_Water_Path_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & Lmodis_subcolumn = .true. ! ISCCP subcolumn if (associated(cospOUT%isccp_boxtau) .or. & associated(cospOUT%isccp_boxptop)) & Lisccp_subcolumn = .true. ! MISR subcolumn if (associated(cospOUT%misr_dist_model_layertops)) & Lmisr_subcolumn = .true. ! CALIPOSO subcolumn if (associated(cospOUT%calipso_tau_tot) .or. & associated(cospOUT%calipso_beta_mol) .or. & associated(cospOUT%calipso_temp_tot) .or. & associated(cospOUT%calipso_betaperp_tot) .or. & associated(cospOUT%calipso_beta_tot)) & Lcalipso_subcolumn = .true. ! PARASOL subcolumn if (associated(cospOUT%parasolPix_refl)) & Lparasol_subcolumn = .true. ! RTTOV column if (associated(cospOUT%rttov_tbs)) & Lrttov_column = .true. ! Set flag to deallocate rttov types (only done on final call to simulator) if (size(cospOUT%isccp_meantb) .eq. stop_idx) lrttov_cleanUp = .true. ! ISCCP column if (associated(cospOUT%isccp_fq) .or. & associated(cospOUT%isccp_meanalbedocld) .or. & associated(cospOUT%isccp_meanptop) .or. & associated(cospOUT%isccp_meantaucld) .or. & associated(cospOUT%isccp_totalcldarea) .or. & associated(cospOUT%isccp_meantb)) then Lisccp_column = .true. Lisccp_subcolumn = .true. endif ! MISR column if (associated(cospOUT%misr_cldarea) .or. & associated(cospOUT%misr_meanztop) .or. & associated(cospOUT%misr_fq)) then Lmisr_column = .true. Lmisr_subcolumn = .true. endif ! CALIPSO column if (associated(cospOUT%calipso_cfad_sr) .or. & associated(cospOUT%calipso_lidarcld) .or. & associated(cospOUT%calipso_lidarcldphase) .or. & associated(cospOUT%calipso_cldlayer) .or. & associated(cospOUT%calipso_cldlayerphase) .or. & associated(cospOUT%calipso_lidarcldtmp)) then Lcalipso_column = .true. Lcalipso_subcolumn = .true. endif ! PARASOL column if (associated(cospOUT%parasolGrid_refl)) then Lparasol_column = .true. Lparasol_subcolumn = .true. endif ! CLOUDSAT column if (associated(cospOUT%cloudsat_cfad_ze)) then Lcloudsat_column = .true. Lcloudsat_subcolumn = .true. endif ! MODIS column if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Water_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Ice_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_High_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Mid_Mean) .or. & associated(cospOUT%modis_Cloud_Fraction_Low_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Total_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Water_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Ice_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_Total_LogMean) .or. & associated(cospOUT%modis_Optical_Thickness_Water_LogMean) .or. & associated(cospOUT%modis_Optical_Thickness_Ice_LogMean) .or. & associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean) .or. & associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean) .or. & associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean) .or. & associated(cospOUT%modis_Liquid_Water_Path_Mean) .or. & associated(cospOUT%modis_Ice_Water_Path_Mean) .or. & associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) then Lmodis_column = .true. Lmodis_subcolumn = .true. endif ! Joint simulator products if (associated(cospOUT%lidar_only_freq_cloud) .or. associated(cospOUT%radar_lidar_tcc)) then Lcalipso_column = .true. Lcalipso_subcolumn = .true. Lcloudsat_column = .true. Lcloudsat_subcolumn = .true. Lradar_lidar_tcc = .true. Llidar_only_freq_cloud = .true. endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 2b) Error Checking ! Enforce bounds on input fields. If input field is out-of-bounds, report error ! and turn off simulator !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% call cosp_errorCheck(cospgridIN,cospIN,Lisccp_subcolumn,Lisccp_column, & Lmisr_subcolumn,Lmisr_column,Lmodis_subcolumn,Lmodis_column, & Lcloudsat_subcolumn,Lcloudsat_column,Lcalipso_subcolumn, & Lcalipso_column,Lrttov_subcolumn,Lrttov_column, & Lparasol_subcolumn,Lparasol_column,Lradar_lidar_tcc, & Llidar_only_freq_cloud,cospOUT,cosp_simulator,nError) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 3) Populate instrument simulator inputs !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (Lisccp_subcolumn .or. Lmodis_subcolumn) then isccpIN%Npoints => Npoints isccpIN%Ncolumns => cospIN%Ncolumns isccpIN%Nlevels => cospIN%Nlevels isccpIN%emsfc_lw => cospIN%emsfc_lw isccpIN%skt => cospgridIN%skt isccpIN%qv => cospgridIN%qv isccpIN%at => cospgridIN%at isccpIN%frac_out => cospIN%frac_out isccpIN%dtau => cospIN%tau_067 isccpIN%dem => cospIN%emiss_11 isccpIN%phalf => cospgridIN%phalf isccpIN%sunlit => cospgridIN%sunlit isccpIN%pfull => cospgridIN%pfull endif if (Lmisr_subcolumn) then misrIN%Npoints => Npoints misrIN%Ncolumns => cospIN%Ncolumns misrIN%Nlevels => cospIN%Nlevels misrIN%dtau => cospIN%tau_067 misrIN%sunlit => cospgridIN%sunlit misrIN%zfull => cospgridIN%hgt_matrix misrIN%at => cospgridIN%at endif if (Lcalipso_subcolumn) then calipsoIN%Npoints => Npoints calipsoIN%Ncolumns => cospIN%Ncolumns calipsoIN%Nlevels => cospIN%Nlevels calipsoIN%beta_mol => cospIN%beta_mol calipsoIN%betatot => cospIN%betatot calipsoIN%betatot_liq => cospIN%betatot_liq calipsoIN%betatot_ice => cospIN%betatot_ice calipsoIN%tau_mol => cospIN%tau_mol calipsoIN%tautot => cospIN%tautot calipsoIN%tautot_liq => cospIN%tautot_liq calipsoIN%tautot_ice => cospIN%tautot_ice endif if (Lparasol_subcolumn) then parasolIN%Npoints => Npoints parasolIN%Nlevels => cospIN%Nlevels parasolIN%Ncolumns => cospIN%Ncolumns parasolIN%Nrefl => cospIN%Nrefl parasolIN%tautot_S_liq => cospIN%tautot_S_liq parasolIN%tautot_S_ice => cospIN%tautot_S_ice endif if (Lcloudsat_subcolumn) then cloudsatIN%Npoints => Npoints cloudsatIN%Nlevels => cospIN%Nlevels cloudsatIN%Ncolumns => cospIN%Ncolumns cloudsatIN%z_vol => cospIN%z_vol_cloudsat cloudsatIN%kr_vol => cospIN%kr_vol_cloudsat cloudsatIN%g_vol => cospIN%g_vol_cloudsat cloudsatIN%rcfg => cospIN%rcfg_cloudsat cloudsatIN%hgt_matrix => cospgridIN%hgt_matrix endif if (Lmodis_subcolumn) then modisIN%Ncolumns => cospIN%Ncolumns modisIN%Nlevels => cospIN%Nlevels modisIN%Npoints => Npoints modisIN%liqFrac => cospIN%fracLiq modisIN%tau => cospIN%tau_067 modisIN%g => cospIN%asym modisIN%w0 => cospIN%ss_alb modisIN%Nsunlit = count(cospgridIN%sunlit > 0) if (modisIN%Nsunlit .gt. 0) then allocate(modisIN%sunlit(modisIN%Nsunlit),modisIN%pres(modisIN%Nsunlit,cospIN%Nlevels+1)) modisIN%sunlit = pack((/ (i, i = 1, Npoints ) /),mask = cospgridIN%sunlit > 0) modisIN%pres = cospgridIN%phalf(int(modisIN%sunlit(:)),:) endif if (count(cospgridIN%sunlit <= 0) .gt. 0) then allocate(modisIN%notSunlit(count(cospgridIN%sunlit <= 0))) modisIN%notSunlit = pack((/ (i, i = 1, Npoints ) /),mask = .not. cospgridIN%sunlit > 0) endif endif ! if (Lrttov_column) then ! rttovIN%nPoints => Npoints ! rttovIN%nLevels => cospIN%nLevels ! rttovIN%nSubCols => cospIN%nColumns ! rttovIN%zenang => cospgridIN%zenang ! rttovIN%co2 => cospgridIN%co2 ! rttovIN%ch4 => cospgridIN%ch4 ! rttovIN%n2o => cospgridIN%n2o ! rttovIN%co => cospgridIN%co ! rttovIN%surfem => cospgridIN%emis_sfc ! rttovIN%h_surf => cospgridIN%hgt_matrix_half(:,cospIN%Nlevels+1) ! rttovIN%u_surf => cospgridIN%u_sfc ! rttovIN%v_surf => cospgridIN%v_sfc ! rttovIN%t_skin => cospgridIN%skt ! rttovIN%p_surf => cospgridIN%phalf(:,cospIN%Nlevels+1) ! rttovIN%q2m => cospgridIN%qv(:,cospIN%Nlevels) ! rttovIN%t2m => cospgridIN%at(:,cospIN%Nlevels) ! rttovIN%lsmask => cospgridIN%land ! rttovIN%latitude => cospgridIN%lat ! rttovIN%longitude => cospgridIN%lon ! rttovIN%seaice => cospgridIN%seaice ! rttovIN%p => cospgridIN%pfull ! rttovIN%ph => cospgridIN%phalf ! rttovIN%t => cospgridIN%at ! rttovIN%q => cospgridIN%qv ! rttovIN%o3 => cospgridIN%o3 ! ! Below only needed for all-sky RTTOV calculation ! rttovIN%month => cospgridIN%month ! rttovIN%tca => cospgridIN%tca ! rttovIN%cldIce => cospgridIN%cloudIce ! rttovIN%cldLiq => cospgridIN%cloudLiq ! rttovIN%fl_rain => cospgridIN%fl_rain ! rttovIN%fl_snow => cospgridIN%fl_snow ! endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 4) Call subcolumn simulators !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! ISCCP (icarus) subcolumn simulator if (Lisccp_subcolumn .or. Lmodis_subcolumn) then ! Allocate space for local variables allocate(isccpLEVMATCH(Npoints,isccpIN%Ncolumns), & isccp_boxttop(Npoints,isccpIN%Ncolumns), & isccp_boxptop(Npoints,isccpIN%Ncolumns), & isccp_boxtau(Npoints,isccpIN%Ncolumns), isccp_meantbclr(Npoints)) ! Call simulator call icarus_subcolumn(isccpIN%npoints,isccpIN%ncolumns,isccpIN%nlevels, & isccpIN%sunlit,isccpIN%dtau,isccpIN%dem,isccpIN%skt, & isccpIN%emsfc_lw,isccpIN%qv,isccpIN%at,isccpIN%pfull, & isccpIN%phalf,isccpIN%frac_out,isccpLEVMATCH, & isccp_boxtau(:,:),isccp_boxptop(:,:), & isccp_boxttop(:,:),isccp_meantbclr(:)) ! Store output (if requested) if (associated(cospOUT%isccp_boxtau)) then cospOUT%isccp_boxtau(ij:ik,:) = isccp_boxtau endif if (associated(cospOUT%isccp_boxptop)) then cospOUT%isccp_boxptop(ij:ik,:) = isccp_boxptop endif if (associated(cospOUT%isccp_meantbclr)) then cospOUT%isccp_meantbclr(ij:ik) = isccp_meantbclr endif endif ! MISR subcolumn simulator if (Lmisr_subcolumn) then ! Allocate space for local variables allocate(misr_boxztop(Npoints,misrIN%Ncolumns), & misr_boxtau(Npoints,misrIN%Ncolumns), & misr_dist_model_layertops(Npoints,numMISRHgtBins)) ! Call simulator call misr_subcolumn(misrIN%Npoints,misrIN%Ncolumns,misrIN%Nlevels,misrIN%dtau, & misrIN%zfull,misrIN%at,misrIN%sunlit,misr_boxtau, & misr_dist_model_layertops,misr_boxztop) ! Store output (if requested) if (associated(cospOUT%misr_dist_model_layertops)) then cospOUT%misr_dist_model_layertops(ij:ik,:) = misr_dist_model_layertops endif endif ! Calipso subcolumn simulator if (Lcalipso_subcolumn) then ! Allocate space for local variables allocate(calipso_beta_mol(calipsoIN%Npoints,calipsoIN%Nlevels), & calipso_beta_tot(calipsoIN%Npoints,calipsoIN%Ncolumns,calipsoIN%Nlevels),& calipso_betaperp_tot(calipsoIN%Npoints,calipsoIN%Ncolumns,calipsoIN%Nlevels)) ! Call simulator call lidar_subcolumn(calipsoIN%npoints,calipsoIN%ncolumns,calipsoIN%nlevels, & calipsoIN%beta_mol,calipsoIN%tau_mol, & calipsoIN%betatot,calipsoIN%tautot,calipsoIN%betatot_ice, & calipsoIN%tautot_ice,calipsoIN%betatot_liq, & calipsoIN%tautot_liq,calipso_beta_mol(:,:), & calipso_beta_tot(:,:,:),calipso_betaperp_tot(:,:,:)) ! Store output (if requested) if (associated(cospOUT%calipso_beta_mol)) & cospOUT%calipso_beta_mol(ij:ik,calipsoIN%Nlevels:1:-1) = calipso_beta_mol if (associated(cospOUT%calipso_beta_tot)) & cospOUT%calipso_beta_tot(ij:ik,:,calipsoIN%Nlevels:1:-1) = calipso_beta_tot if (associated(cospOUT%calipso_betaperp_tot)) & cospOUT%calipso_betaperp_tot(ij:ik,:,:) = calipso_betaperp_tot endif ! PARASOL subcolumn simulator if (Lparasol_subcolumn) then ! Allocate space for local variables allocate(parasolPix_refl(parasolIN%Npoints,parasolIN%Ncolumns,PARASOL_NREFL)) ! Call simulator do icol=1,parasolIN%Ncolumns call parasol_subcolumn(parasolIN%npoints, PARASOL_NREFL, & parasolIN%tautot_S_liq(1:parasolIN%Npoints,icol), & parasolIN%tautot_S_ice(1:parasolIN%Npoints,icol), & parasolPix_refl(:,icol,1:PARASOL_NREFL)) ! Store output (if requested) if (associated(cospOUT%parasolPix_refl)) then cospOUT%parasolPix_refl(ij:ik,icol,1:PARASOL_NREFL) = & parasolPix_refl(:,icol,1:PARASOL_NREFL) endif enddo endif ! Cloudsat (quickbeam) subcolumn simulator if (Lcloudsat_subcolumn) then ! Allocate space for local variables allocate(cloudsatDBZe(cloudsatIN%Npoints,cloudsatIN%Ncolumns,cloudsatIN%Nlevels)) do icol=1,cloudsatIN%ncolumns call quickbeam_subcolumn(cloudsatIN%rcfg,cloudsatIN%Npoints,cloudsatIN%Nlevels,& cloudsatIN%hgt_matrix/1000._wp, & cloudsatIN%z_vol(:,icol,:), & cloudsatIN%kr_vol(:,icol,:), & cloudsatIN%g_vol(:,1,:),cloudsatDBze(:,icol,:)) enddo ! Store output (if requested) if (associated(cospOUT%cloudsat_Ze_tot)) then cospOUT%cloudsat_Ze_tot(ij:ik,:,:) = cloudsatDBZe(:,:,cloudsatIN%Nlevels:1:-1) endif endif if (Lmodis_subcolumn) then if(modisiN%nSunlit > 0) then ! Allocate space for local variables allocate(modisRetrievedTau(modisIN%nSunlit,modisIN%nColumns), & modisRetrievedSize(modisIN%nSunlit,modisIN%nColumns), & modisRetrievedPhase(modisIN%nSunlit,modisIN%nColumns), & modisRetrievedCloudTopPressure(modisIN%nSunlit,modisIN%nColumns)) ! Call simulator do i = 1, modisIN%nSunlit call modis_subcolumn(modisIN%Ncolumns,modisIN%Nlevels,modisIN%pres(i,:), & modisIN%tau(int(modisIN%sunlit(i)),:,:), & modisIN%liqFrac(int(modisIN%sunlit(i)),:,:), & modisIN%g(int(modisIN%sunlit(i)),:,:), & modisIN%w0(int(modisIN%sunlit(i)),:,:), & isccp_boxptop(int(modisIN%sunlit(i)),:), & modisRetrievedPhase(i,:), & modisRetrievedCloudTopPressure(i,:), & modisRetrievedTau(i,:),modisRetrievedSize(i,:)) end do endif endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 5) Call column simulators !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! ISCCP if (Lisccp_column) then ! Check to see which outputs are requested. If not requested, use a local dummy array if(.not. associated(cospOUT%isccp_meanalbedocld)) then allocate(out1D_1(Npoints)) cospOUT%isccp_meanalbedocld(ij:ik) => out1D_1 endif if(.not. associated(cospOUT%isccp_meanptop)) then allocate(out1D_2(Npoints)) cospOUT%isccp_meanptop(ij:ik) => out1D_2 endif if(.not. associated(cospOUT%isccp_meantaucld)) then allocate(out1D_3(Npoints)) cospOUT%isccp_meantaucld(ij:ik) => out1D_3 endif if(.not. associated(cospOUT%isccp_totalcldarea)) then allocate(out1D_4(Npoints)) cospOUT%isccp_totalcldarea(ij:ik) => out1D_4 endif if(.not. associated(cospOUT%isccp_meantb)) then allocate(out1D_5(Npoints)) cospOUT%isccp_meantb(ij:ik) => out1D_5 endif if(.not. associated(cospOUT%isccp_fq)) then allocate(out1D_6(Npoints*numISCCPTauBins*numISCCPPresBins)) cospOUT%isccp_fq(ij:ik,1:numISCCPTauBins,1:numISCCPPresBins) => out1D_6 endif ! Call simulator call icarus_column(isccpIN%npoints, isccpIN%ncolumns,isccp_boxtau(:,:), & isccp_boxptop(:,:)/100._wp, isccpIN%sunlit,isccp_boxttop, & cospOUT%isccp_fq(ij:ik,:,:), & cospOUT%isccp_meanalbedocld(ij:ik), & cospOUT%isccp_meanptop(ij:ik),cospOUT%isccp_meantaucld(ij:ik), & cospOUT%isccp_totalcldarea(ij:ik),cospOUT%isccp_meantb(ij:ik)) cospOUT%isccp_fq(ij:ik,:,:) = cospOUT%isccp_fq(ij:ik,:,7:1:-1) ! Check if there is any value slightly greater than 1 where ((cospOUT%isccp_totalcldarea > 1.0-1.e-5) .and. & (cospOUT%isccp_totalcldarea < 1.0+1.e-5)) cospOUT%isccp_totalcldarea = 1.0 endwhere ! Clear up memory (if necessary) if (allocated(isccp_boxttop)) deallocate(isccp_boxttop) if (allocated(isccp_boxptop)) deallocate(isccp_boxptop) if (allocated(isccp_boxtau)) deallocate(isccp_boxtau) if (allocated(isccp_meantbclr)) deallocate(isccp_meantbclr) if (allocated(isccpLEVMATCH)) deallocate(isccpLEVMATCH) if (allocated(out1D_1)) then deallocate(out1D_1) nullify(cospOUT%isccp_meanalbedocld) endif if (allocated(out1D_2)) then deallocate(out1D_2) nullify(cospOUT%isccp_meanptop) endif if (allocated(out1D_3)) then deallocate(out1D_3) nullify(cospOUT%isccp_meantaucld) endif if (allocated(out1D_4)) then deallocate(out1D_4) nullify(cospOUT%isccp_totalcldarea) endif if (allocated(out1D_5)) then deallocate(out1D_5) nullify(cospOUT%isccp_meantb) endif if (allocated(out1D_6)) then deallocate(out1D_6) nullify(cospOUT%isccp_fq) endif endif ! MISR if (Lmisr_column) then ! Check to see which outputs are requested. If not requested, use a local dummy array if (.not. associated(cospOUT%misr_cldarea)) then allocate(out1D_1(Npoints)) cospOUT%misr_cldarea(ij:ik) => out1D_1 endif if (.not. associated(cospOUT%misr_meanztop)) then allocate(out1D_2(Npoints)) cospOUT%misr_meanztop(ij:ik) => out1D_2 endif if (.not. associated(cospOUT%misr_fq)) then allocate(out1D_3(Npoints*numMISRTauBins*numMISRHgtBins)) cospOUT%misr_fq(ij:ik,1:numMISRTauBins,1:numMISRHgtBins) => out1D_3 endif ! Call simulator call misr_column(misrIN%Npoints,misrIN%Ncolumns,misr_boxztop,misrIN%sunlit,& misr_boxtau,cospOUT%misr_cldarea(ij:ik), & cospOUT%misr_meanztop(ij:ik),cospOUT%misr_fq(ij:ik,:,:)) ! Clear up memory if (allocated(misr_boxtau)) deallocate(misr_boxtau) if (allocated(misr_boxztop)) deallocate(misr_boxztop) if (allocated(misr_dist_model_layertops)) deallocate(misr_dist_model_layertops) if (allocated(out1D_1)) then deallocate(out1D_1) nullify(cospOUT%misr_cldarea) endif if (allocated(out1D_2)) then deallocate(out1D_2) nullify(cospOUT%misr_meanztop) endif if (allocated(out1D_3)) then deallocate(out1D_3) nullify(cospOUT%misr_fq) endif endif ! CALIPSO LIDAR Simulator if (Lcalipso_column) then ! Check to see which outputs are requested. If not requested, use a local dummy array if (.not. associated(cospOUT%calipso_cfad_sr)) then allocate(out1D_1(Npoints*SR_BINS*Nlvgrid)) cospOUT%calipso_cfad_sr(ij:ik,1:SR_BINS,1:Nlvgrid) => out1D_1 endif if (.not. associated(cospOUT%calipso_lidarcld)) then allocate(out1D_2(Npoints*Nlvgrid)) cospOUT%calipso_lidarcld(ij:ik,1:Nlvgrid) => out1D_2 endif if (.not. associated(cospOUT%calipso_lidarcldphase)) then allocate(out1D_3(Npoints*Nlvgrid*6)) cospOUT%calipso_lidarcldphase(ij:ik,1:Nlvgrid,1:6) => out1D_3 endif if (.not. associated(cospOUT%calipso_cldlayer)) then allocate(out1D_4(Npoints*LIDAR_NCAT)) cospOUT%calipso_cldlayer(ij:ik,1:LIDAR_NCAT) => out1D_4 endif if (.not. associated(cospOUT%calipso_cldlayerphase)) then allocate(out1D_5(Npoints*LIDAR_NCAT*6)) cospOUT%calipso_cldlayerphase(ij:ik,1:LIDAR_NCAT,1:6) => out1D_5 endif if (.not. associated(cospOUT%calipso_lidarcldtmp)) then allocate(out1D_6(Npoints*40*5)) cospOUT%calipso_lidarcldtmp(ij:ik,1:40,1:5) => out1D_6 endif ! Call simulator ok_lidar_cfad=.true. call lidar_column(calipsoIN%Npoints,calipsoIN%Ncolumns,calipsoIN%Nlevels, & Nlvgrid,SR_BINS,cospgridIN%at(:,:), & calipso_beta_tot(:,:,:),calipso_betaperp_tot(:,:,:), & calipso_beta_mol(:,:), & cospgridIN%phalf(:,2:calipsoIN%Nlevels),ok_lidar_cfad, & LIDAR_NCAT,cospOUT%calipso_cfad_sr(ij:ik,:,:), & cospOUT%calipso_lidarcld(ij:ik,:), & cospOUT%calipso_lidarcldphase(ij:ik,:,:), & cospOUT%calipso_cldlayer(ij:ik,:), & cospgridIN%hgt_matrix,cospgridIN%hgt_matrix_half, & cospOUT%calipso_cldlayerphase(ij:ik,:,:), & cospOUT%calipso_lidarcldtmp(ij:ik,:,:)) if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval = calipso_histBsct ! Free up memory (if necessary) if (allocated(out1D_1)) then deallocate(out1D_1) nullify(cospOUT%calipso_cfad_sr) endif if (allocated(out1D_2)) then deallocate(out1D_2) nullify(cospOUT%calipso_lidarcld) endif if (allocated(out1D_3)) then deallocate(out1D_3) nullify(cospOUT%calipso_lidarcldphase) endif if (allocated(out1D_4)) then deallocate(out1D_4) nullify(cospOUT%calipso_cldlayer) endif if (allocated(out1D_5)) then deallocate(out1D_5) nullify(cospOUT%calipso_cldlayerphase) endif if (allocated(out1D_6)) then deallocate(out1D_6) nullify(cospOUT%calipso_lidarcldtmp) endif endif ! PARASOL if (Lparasol_column) then call parasol_column(parasolIN%Npoints,PARASOL_NREFL,parasolIN%Ncolumns, & cospgridIN%land(:),parasolPix_refl(:,:,:), & cospOUT%parasolGrid_refl(ij:ik,:)) if (allocated(parasolPix_refl)) deallocate(parasolPix_refl) endif ! CLOUDSAT if (Lcloudsat_column) then ! Check to see which outputs are requested. If not requested, use a local dummy array if (.not. associated(cospOUT%cloudsat_cfad_ze)) then allocate(out1D_1(Npoints*DBZE_BINS*Nlvgrid)) cospOUT%cloudsat_cfad_ze(ij:ik,1:DBZE_BINS,1:Nlvgrid) => out1D_1 endif ! Call simulator call quickbeam_column(cloudsatIN%Npoints,cloudsatIN%Ncolumns,cloudsatIN%Nlevels, & Nlvgrid,cloudsatDBZe,cospgridIN%hgt_matrix, & cospgridIN%hgt_matrix_half,cospOUT%cloudsat_cfad_ze(ij:ik,:,:)) ! Free up memory (if necessary) if (allocated(out1D_1)) then deallocate(out1D_1) nullify(cospOUT%cloudsat_cfad_ze) endif endif ! MODIS if (Lmodis_column) then if(modisiN%nSunlit > 0) then ! Allocate space for local variables allocate(modisCftotal(modisIN%nSunlit), modisCfLiquid(modisIN%nSunlit), & modisCfIce(modisIN%nSunlit),modisCfHigh(modisIN%nSunlit), & modisCfMid(modisIN%nSunlit),modisCfLow(modisIN%nSunlit), & modisMeanTauTotal(modisIN%nSunlit), & modisMeanTauLiquid(modisIN%nSunlit),modisMeanTauIce(modisIN%nSunlit), & modisMeanLogTauTotal(modisIN%nSunlit), & modisMeanLogTauLiquid(modisIN%nSunlit), & modisMeanLogTauIce(modisIN%nSunlit), & modisMeanSizeLiquid(modisIN%nSunlit), & modisMeanSizeIce(modisIN%nSunlit), & modisMeanCloudTopPressure(modisIN%nSunlit), & modisMeanLiquidWaterPath(modisIN%nSunlit), & modisMeanIceWaterPath(modisIN%nSunlit), & modisJointHistogram(modisIN%nSunlit,numMODISTauBins,numMODISPresBins),& modisJointHistogramIce(modisIN%nSunlit,numModisTauBins,numMODISReffIceBins),& modisJointHistogramLiq(modisIN%nSunlit,numModisTauBins,numMODISReffLiqBins)) ! Call simulator call modis_column(modisIN%nSunlit, modisIN%Ncolumns,modisRetrievedPhase, & modisRetrievedCloudTopPressure,modisRetrievedTau, & modisRetrievedSize, modisCfTotal, modisCfLiquid, modisCfIce,& modisCfHigh, modisCfMid, modisCfLow, modisMeanTauTotal, & modisMeanTauLiquid, modisMeanTauIce, modisMeanLogTauTotal, & modisMeanLogTauLiquid, modisMeanLogTauIce, & modisMeanSizeLiquid, modisMeanSizeIce, & modisMeanCloudTopPressure, modisMeanLiquidWaterPath, & modisMeanIceWaterPath, modisJointHistogram, & modisJointHistogramIce,modisJointHistogramLiq) ! Store data (if requested) if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) then cospOUT%modis_Cloud_Fraction_Total_Mean(ij+int(modisIN%sunlit(:))-1) = & modisCfTotal endif if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) then cospOUT%modis_Cloud_Fraction_Water_Mean(ij+int(modisIN%sunlit(:))-1) = & modisCfLiquid endif if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) then cospOUT%modis_Cloud_Fraction_Ice_Mean(ij+int(modisIN%sunlit(:))-1) = & modisCfIce endif if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) then cospOUT%modis_Cloud_Fraction_High_Mean(ij+int(modisIN%sunlit(:))-1) = & modisCfHigh endif if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) then cospOUT%modis_Cloud_Fraction_Mid_Mean(ij+int(modisIN%sunlit(:))-1) = & modisCfMid endif if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) then cospOUT%modis_Cloud_Fraction_Low_Mean(ij+int(modisIN%sunlit(:))-1) = & modisCfLow endif if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) then cospOUT%modis_Optical_Thickness_Total_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanTauTotal endif if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) then cospOUT%modis_Optical_Thickness_Water_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanTauLiquid endif if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) then cospOUT%modis_Optical_Thickness_Ice_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanTauIce endif if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) then cospOUT%modis_Optical_Thickness_Total_LogMean(ij+int(modisIN%sunlit(:))-1)= & modisMeanLogTauTotal endif if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) then cospOUT%modis_Optical_Thickness_Water_LogMean(ij+int(modisIN%sunlit(:))-1) = & modisMeanLogTauLiquid endif if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) then cospOUT%modis_Optical_Thickness_Ice_LogMean(ij+int(modisIN%sunlit(:))-1) = & modisMeanLogTauIce endif if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) then cospOUT%modis_Cloud_Particle_Size_Water_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanSizeLiquid endif if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) then cospOUT%modis_Cloud_Particle_Size_Ice_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanSizeIce endif if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) then cospOUT%modis_Cloud_Top_Pressure_Total_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanCloudTopPressure endif if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) then cospOUT%modis_Liquid_Water_Path_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanLiquidWaterPath endif if (associated(cospOUT%modis_Ice_Water_Path_Mean)) then cospOUT%modis_Ice_Water_Path_Mean(ij+int(modisIN%sunlit(:))-1) = & modisMeanIceWaterPath endif if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) then cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(ij+ & int(modisIN%sunlit(:))-1, 1:numModisTauBins, :) = modisJointHistogram(:, :, :) ! Reorder pressure bins in joint histogram to go from surface to TOA cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(ij:ik,:,:) = & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(ij:ik,:,numMODISPresBins:1:-1) endif if (associated(cospOUT%modis_Optical_Thickness_vs_ReffIce)) then cospOUT%modis_Optical_Thickness_vs_ReffIce(ij+int(modisIN%sunlit(:))-1, 1:numMODISTauBins,:) = & modisJointHistogramIce(:,:,:) endif if (associated(cospOUT%modis_Optical_Thickness_vs_ReffLiq)) then cospOUT%modis_Optical_Thickness_vs_ReffLiq(ij+int(modisIN%sunlit(:))-1, 1:numMODISTauBins,:) = & modisJointHistogramLiq(:,:,:) endif if(modisIN%nSunlit < modisIN%Npoints) then ! Where it's night and we haven't done the retrievals the values are undefined if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(ij+int(modisIN%notSunlit(:))-1) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(ij+int(modisIN%notSunlit(:))-1, :, :) = R_UNDEF end if else ! It's nightime everywhere - everything is undefined if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(ij:ik) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(ij:ik, :, :) = R_UNDEF endif ! Free up memory (if necessary) if (allocated(modisRetrievedTau)) deallocate(modisRetrievedTau) if (allocated(modisRetrievedSize)) deallocate(modisRetrievedSize) if (allocated(modisRetrievedPhase)) deallocate(modisRetrievedPhase) if (allocated(modisRetrievedCloudTopPressure)) deallocate(modisRetrievedCloudTopPressure) if (allocated(modisCftotal)) deallocate(modisCftotal) if (allocated(modisCfLiquid)) deallocate(modisCfLiquid) if (allocated(modisCfIce)) deallocate(modisCfIce) if (allocated(modisCfHigh)) deallocate(modisCfHigh) if (allocated(modisCfMid)) deallocate(modisCfMid) if (allocated(modisCfLow)) deallocate(modisCfLow) if (allocated(modisMeanTauTotal)) deallocate(modisMeanTauTotal) if (allocated(modisMeanTauLiquid)) deallocate(modisMeanTauLiquid) if (allocated(modisMeanTauIce)) deallocate(modisMeanTauIce) if (allocated(modisMeanLogTauTotal)) deallocate(modisMeanLogTauTotal) if (allocated(modisMeanLogTauLiquid)) deallocate(modisMeanLogTauLiquid) if (allocated(modisMeanLogTauIce)) deallocate(modisMeanLogTauIce) if (allocated(modisMeanSizeLiquid)) deallocate(modisMeanSizeLiquid) if (allocated(modisMeanSizeIce)) deallocate(modisMeanSizeIce) if (allocated(modisMeanCloudTopPressure)) deallocate(modisMeanCloudTopPressure) if (allocated(modisMeanLiquidWaterPath)) deallocate(modisMeanLiquidWaterPath) if (allocated(modisMeanIceWaterPath)) deallocate(modisMeanIceWaterPath) if (allocated(modisJointHistogram)) deallocate(modisJointHistogram) if (allocated(modisJointHistogramIce)) deallocate(modisJointHistogramIce) if (allocated(modisJointHistogramLiq)) deallocate(modisJointHistogramLiq) if (allocated(isccp_boxttop)) deallocate(isccp_boxttop) if (allocated(isccp_boxptop)) deallocate(isccp_boxptop) if (allocated(isccp_boxtau)) deallocate(isccp_boxtau) if (allocated(isccp_meantbclr)) deallocate(isccp_meantbclr) if (allocated(isccpLEVMATCH)) deallocate(isccpLEVMATCH) endif ! RTTOV ! if (lrttov_column) then ! call rttov_column(rttovIN%nPoints,rttovIN%nLevels,rttovIN%nSubCols,rttovIN%q, & ! rttovIN%p,rttovIN%t,rttovIN%o3,rttovIN%ph,rttovIN%h_surf, & ! rttovIN%u_surf,rttovIN%v_surf,rttovIN%p_surf,rttovIN%t_skin, & ! rttovIN%t2m,rttovIN%q2m,rttovIN%lsmask,rttovIN%longitude, & ! rttovIN%latitude,rttovIN%seaice,rttovIN%co2,rttovIN%ch4, & ! rttovIN%n2o,rttovIN%co,rttovIN%zenang,lrttov_cleanUp, & ! cospOUT%rttov_tbs(ij:ik,:),cosp_simulator(nError+1), & ! ! Optional arguments for surface emissivity calculation ! month=rttovIN%month) ! ! Optional arguments to rttov for all-sky calculation ! ! rttovIN%month, rttovIN%tca,rttovIN%cldIce,rttovIN%cldLiq, & ! ! rttovIN%fl_rain,rttovIN%fl_snow) ! endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 6) Compute multi-instrument products !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! CLOUDSAT/CALIPSO products if (Lradar_lidar_tcc .or. Llidar_only_freq_cloud) then if (use_vgrid) then allocate(lidar_only_freq_cloud(cloudsatIN%Npoints,Nlvgrid), & radar_lidar_tcc(cloudsatIN%Npoints)) allocate(betamol_in(cloudsatIN%Npoints,1,cloudsatIN%Nlevels), & betamolFlip(cloudsatIN%Npoints,1,Nlvgrid), & pnormFlip(cloudsatIN%Npoints,cloudsatIN%Ncolumns,Nlvgrid), & Ze_totFlip(cloudsatIN%Npoints,cloudsatIN%Ncolumns,Nlvgrid)) betamol_in(:,1,:) = calipso_beta_mol(:,cloudsatIN%Nlevels:1:-1) call cosp_change_vertical_grid(cloudsatIN%Npoints,1,cloudsatIN%Nlevels, & cospgridIN%hgt_matrix(:,cloudsatIN%Nlevels:1:-1), & cospgridIN%hgt_matrix_half(:,cloudsatIN%Nlevels:1:-1),betamol_in, & Nlvgrid,vgrid_zl(Nlvgrid:1:-1),vgrid_zu(Nlvgrid:1:-1), & betamolFlip(:,1,Nlvgrid:1:-1)) call cosp_change_vertical_grid(cloudsatIN%Npoints,cloudsatIN%Ncolumns, & cloudsatIN%Nlevels,cospgridIN%hgt_matrix(:,cloudsatIN%Nlevels:1:-1), & cospgridIN%hgt_matrix_half(:,cloudsatIN%Nlevels:1:-1), & calipso_beta_tot(:,:,cloudsatIN%Nlevels:1:-1),Nlvgrid, & vgrid_zl(Nlvgrid:1:-1),vgrid_zu(Nlvgrid:1:-1),pnormFlip(:,:,Nlvgrid:1:-1)) call cosp_change_vertical_grid(cloudsatIN%Npoints,cloudsatIN%Ncolumns, & cloudsatIN%Nlevels,cospgridIN%hgt_matrix(:,cloudsatIN%Nlevels:1:-1), & cospgridIN%hgt_matrix_half(:,cloudsatIN%Nlevels:1:-1), & cloudsatDBZe(:,:,cloudsatIN%Nlevels:1:-1),Nlvgrid,vgrid_zl(Nlvgrid:1:-1), & vgrid_zu(Nlvgrid:1:-1),Ze_totFlip(:,:,Nlvgrid:1:-1),log_units=.true.) call cosp_lidar_only_cloud(cloudsatIN%Npoints,cloudsatIN%Ncolumns, & Nlvgrid,pnormFlip,betamolFlip,Ze_totFlip, & lidar_only_freq_cloud,radar_lidar_tcc) deallocate(betamol_in,betamolFlip,pnormFlip,ze_totFlip) else allocate(lidar_only_freq_cloud(cloudsatIN%Npoints,cloudsatIN%Nlevels), & radar_lidar_tcc(cloudsatIN%Npoints)) call cosp_lidar_only_cloud(cloudsatIN%Npoints,cloudsatIN%Ncolumns, & cospIN%Nlevels,calipso_beta_tot(:,:,cloudsatIN%Nlevels:1:-1), & calipso_beta_mol(:,cloudsatIN%Nlevels:1:-1), & cloudsatDBZe(:,:,cloudsatIN%Nlevels:1:-1),lidar_only_freq_cloud, & radar_lidar_tcc) endif ! Store, when necessary if (associated(cospOUT%lidar_only_freq_cloud)) then cospOUT%lidar_only_freq_cloud(ij:ik,:) = lidar_only_freq_cloud endif if (associated(cospOUT%radar_lidar_tcc)) then cospOUT%radar_lidar_tcc(ij:ik) = radar_lidar_tcc endif endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 7) Cleanup !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (Lisccp_subcolumn .or. Lmodis_subcolumn) then nullify(isccpIN%Npoints,isccpIN%Ncolumns,isccpIN%Nlevels,isccpIN%emsfc_lw, & isccpIN%skt,isccpIN%qv,isccpIN%at,isccpIN%frac_out,isccpIN%dtau, & isccpIN%dem,isccpIN%phalf,isccpIN%sunlit,isccpIN%pfull) endif if (Lmisr_subcolumn) then nullify(misrIN%Npoints,misrIN%Ncolumns,misrIN%Nlevels,misrIN%dtau,misrIN%sunlit, & misrIN%zfull,misrIN%at) endif if (Lcalipso_subcolumn) then nullify(calipsoIN%Npoints,calipsoIN%Ncolumns,calipsoIN%Nlevels,calipsoIN%beta_mol,& calipsoIN%betatot,calipsoIN%betatot_liq,calipsoIN%betatot_ice, & calipsoIN%tau_mol,calipsoIN%tautot,calipsoIN%tautot_liq,calipsoIN%tautot_ice) endif if (Lparasol_subcolumn) then nullify(parasolIN%Npoints,parasolIN%Nlevels,parasolIN%Ncolumns,parasolIN%Nrefl, & parasolIN%tautot_S_liq,parasolIN%tautot_S_ice) endif if (Lcloudsat_subcolumn) then nullify(cloudsatIN%Npoints,cloudsatIN%Nlevels,cloudsatIN%Ncolumns,cloudsatIN%rcfg,& cloudsatIN%kr_vol,cloudsatIN%g_vol,cloudsatIN%z_vol,cloudsatIN%hgt_matrix) endif if (Lmodis_subcolumn) then nullify(modisIN%Npoints,modisIN%Ncolumns,modisIN%Nlevels,modisIN%tau,modisIN%g, & modisIN%liqFrac,modisIN%w0) if (allocated(modisIN%sunlit)) deallocate(modisIN%sunlit) if (allocated(modisIN%notSunlit)) deallocate(modisIN%notSunlit) if (allocated(modisIN%pres)) deallocate(modisIN%pres) endif if (allocated(calipso_beta_tot)) deallocate(calipso_beta_tot) if (allocated(calipso_beta_mol)) deallocate(calipso_beta_mol) if (allocated(calipso_betaperp_tot)) deallocate(calipso_betaperp_tot) if (allocated(cloudsatDBZe)) deallocate(cloudsatDBZe) if (allocated(lidar_only_freq_cloud)) deallocate(lidar_only_freq_cloud) if (allocated(radar_lidar_tcc)) deallocate(radar_lidar_tcc) end function COSP_SIMULATOR ! ###################################################################################### ! SUBROUTINE cosp_init ! ###################################################################################### SUBROUTINE COSP_INIT(Lisccp,Lmodis,Lmisr,Lcloudsat,Lcalipso,Lparasol,Lrttov, & Npoints,Nlevels,cloudsat_radar_freq,cloudsat_k2, & cloudsat_use_gas_abs,cloudsat_do_ray,isccp_top_height, & isccp_top_height_direction,surface_radar,rcfg,rttov_Nchannels, & rttov_Channels,rttov_platform,rttov_satellite,rttov_instrument, & lusevgrid,luseCSATvgrid,Nvgrid,cloudsat_micro_scheme,cospOUT) ! INPUTS logical,intent(in) :: Lisccp,Lmodis,Lmisr,Lcloudsat,Lcalipso,Lparasol,Lrttov integer,intent(in) :: & cloudsat_use_gas_abs, & ! cloudsat_do_ray, & ! isccp_top_height, & ! isccp_top_height_direction, & ! Npoints, & ! Nlevels, & ! Nvgrid, & ! Number of levels for new L3 grid surface_radar, & ! rttov_Nchannels, & ! Number of RTTOV channels rttov_platform, & ! RTTOV platform rttov_satellite, & ! RTTOV satellite rttov_instrument ! RTTOV instrument integer,intent(in),dimension(RTTOV_MAX_CHANNELS) :: & rttov_channels ! RTTOV channels real(wp),intent(in) :: & cloudsat_radar_freq, & ! cloudsat_k2 ! logical,intent(in) :: & lusevgrid, & ! Switch to use different vertical grid luseCSATvgrid ! Switch to use CLOUDSAT grid spacing for new ! vertical grid character(len=64),intent(in) :: & cloudsat_micro_scheme ! Microphysical scheme used by CLOUDSAT type(cosp_outputs),intent(inout) :: cospOUT ! OUTPUTS type(radar_cfg) :: rcfg ! Local variables integer :: i real(wp) :: zstep ! Initialize MODIS optical-depth bin boundaries for joint-histogram. (defined in cosp_config.F90) if (.not. allocated(modis_histTau)) then allocate(modis_histTau(ntau+1),modis_histTauEdges(2,ntau),modis_histTauCenters(ntau)) numMODISTauBins = ntau modis_histTau = tau_binBounds modis_histTauEdges = tau_binEdges modis_histTauCenters = tau_binCenters endif ! Set up vertical grid used by CALIPSO and CLOUDSAT L3 use_vgrid = lusevgrid if (use_vgrid) then Nlvgrid = Nvgrid print*,'allocation vgrid_zl zu z dans COSP_INIT' allocate(vgrid_zl(Nlvgrid),vgrid_zu(Nlvgrid),vgrid_z(Nlvgrid)) ! CloudSat grid requested if (luseCSATvgrid) zstep = 480._wp ! Other grid requested. Constant vertical spacing with top at 20 km if (.not. luseCSATvgrid) zstep = 20000._wp/Nvgrid do i=1,Nvgrid vgrid_zl(Nlvgrid-i+1) = (i-1)*zstep vgrid_zu(Nlvgrid-i+1) = i*zstep enddo vgrid_z = (vgrid_zl+vgrid_zu)/2._wp else Nlvgrid = Nlevels allocate(vgrid_zl(Nlvgrid),vgrid_zu(Nlvgrid),vgrid_z(Nlvgrid)) endif ! Initialize simulators if (Lisccp) call cosp_isccp_init(isccp_top_height,isccp_top_height_direction) if (Lmodis) call cosp_modis_init() if (Lmisr) call cosp_misr_init() !if (Lrttov) call cosp_rttov_init(rttov_Nchannels,rttov_platform,rttov_satellite, & ! rttov_instrument,rttov_channels) ! if (Lrttov) call cosp_rttov_init() if (Lcloudsat) call cosp_cloudsat_init(cloudsat_radar_freq,cloudsat_k2, & cloudsat_use_gas_abs,cloudsat_do_ray,R_UNDEF,N_HYDRO, surface_radar, & rcfg,cloudsat_micro_scheme) if (Lcalipso) call cosp_calipso_init() if (Lparasol) call cosp_parasol_init() linitialization = .FALSE. END SUBROUTINE COSP_INIT !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE cosp_cleanUp !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine cosp_cleanUp() deallocate(vgrid_zl,vgrid_zu,vgrid_z) end subroutine cosp_cleanUp !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE cosp_errorCheck !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine cosp_errorCheck(cospgridIN,cospIN,Lisccp_subcolumn,Lisccp_column,Lmisr_subcolumn,Lmisr_column, & Lmodis_subcolumn,Lmodis_column,Lcloudsat_subcolumn,Lcloudsat_column,Lcalipso_subcolumn, & Lcalipso_column,Lrttov_subcolumn,Lrttov_column,Lparasol_subcolumn,Lparasol_column, & Lradar_lidar_tcc,Llidar_only_freq_cloud,cospOUT,errorMessage,nError) ! Inputs type(cosp_column_inputs),intent(in) :: & cospgridIN ! Model grid inputs to COSP type(cosp_optical_inputs),intent(in) :: & cospIN ! Derived (optical) input to COSP ! Outputs logical,intent(inout) :: & Lisccp_subcolumn, & ! ISCCP subcolumn simulator on/off switch Lisccp_column, & ! ISCCP column simulator on/off switch Lmisr_subcolumn, & ! MISR subcolumn simulator on/off switch Lmisr_column, & ! MISR column simulator on/off switch Lmodis_subcolumn, & ! MODIS subcolumn simulator on/off switch Lmodis_column, & ! MODIS column simulator on/off switch Lcloudsat_subcolumn, & ! CLOUDSAT subcolumn simulator on/off switch Lcloudsat_column, & ! CLOUDSAT column simulator on/off switch Lcalipso_subcolumn, & ! CALIPSO subcolumn simulator on/off switch Lcalipso_column, & ! CALIPSO column simulator on/off switch Lparasol_subcolumn, & ! PARASOL subcolumn simulator on/off switch Lparasol_column, & ! PARASOL column simulator on/off switch Lrttov_subcolumn, & ! RTTOV subcolumn simulator on/off switch Lrttov_column, & ! RTTOV column simulator on/off switch Lradar_lidar_tcc, & ! On/Off switch for joint Calipso/Cloudsat product Llidar_only_freq_cloud ! On/Off switch for joint Calipso/Cloudsat product type(cosp_outputs),intent(inout) :: & cospOUT ! COSP Outputs character(len=256),dimension(100) :: errorMessage integer,intent(out) :: nError ! Local variables character(len=100) :: parasolErrorMessage nError = 0 !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! PART 1: Check input array values for out-of-bounds values. When an out-of-bound value ! is encountered, COSP outputs that are dependent on that input are filled with ! an undefined value (set in cosp_config.f90) and if necessary, that simulator ! is turned off. !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (any(cospgridIN%sunlit .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%sunlit contains values out of range (0 or 1)' Lisccp_subcolumn = .false. Lisccp_column = .false. Lmisr_subcolumn = .false. Lmisr_column = .false. Lmodis_subcolumn = .false. Lmodis_column = .false. if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_fq)) cospOUT%misr_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_dist_model_layertops)) cospOUT%misr_dist_model_layertops(:,:) = R_UNDEF if (associated(cospOUT%misr_meanztop)) cospOUT%misr_meanztop(:) = R_UNDEF if (associated(cospOUT%misr_cldarea)) cospOUT%misr_cldarea(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffICE)) & cospOUT%modis_Optical_Thickness_vs_ReffICE(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffLIQ)) & cospOUT%modis_Optical_Thickness_vs_ReffLIQ(:,:,:) = R_UNDEF endif if (any(cospgridIN%at .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%at contains values out of range (at<0), expected units (K)' Lisccp_subcolumn = .false. Lisccp_column = .false. Lmisr_subcolumn = .false. Lmisr_column = .false. Lrttov_subcolumn = .false. Lcalipso_column = .false. Lcloudsat_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_fq)) cospOUT%misr_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_dist_model_layertops)) cospOUT%misr_dist_model_layertops(:,:) = R_UNDEF if (associated(cospOUT%misr_meanztop)) cospOUT%misr_meanztop(:) = R_UNDEF if (associated(cospOUT%misr_cldarea)) cospOUT%misr_cldarea(:) = R_UNDEF if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif if (any(cospgridIN%pfull .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%pfull contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF endif if (any(cospgridIN%phalf .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%phalf contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. Lrttov_subcolumn = .false. Lmodis_subcolumn = .false. Lmodis_column = .false. Lcalipso_column = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffICE)) & cospOUT%modis_Optical_Thickness_vs_ReffICE(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffLIQ)) & cospOUT%modis_Optical_Thickness_vs_ReffLIQ(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF endif if (any(cospgridIN%qv .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%qv contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF endif if (any(cospgridIN%hgt_matrix .lt. -300)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%hgt_matrix contains values out of range' Lmisr_subcolumn = .false. Lmisr_column = .false. Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. Lcalipso_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%misr_fq)) cospOUT%misr_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_dist_model_layertops)) cospOUT%misr_dist_model_layertops(:,:) = R_UNDEF if (associated(cospOUT%misr_meanztop)) cospOUT%misr_meanztop(:) = R_UNDEF if (associated(cospOUT%misr_cldarea)) cospOUT%misr_cldarea(:) = R_UNDEF if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_Ze_tot)) cospOUT%cloudsat_Ze_tot(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif if (any(cospgridIN%hgt_matrix_half .lt. -300)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%hgt_matrix_half contains values out of range' Lrttov_subcolumn = .false. Lcloudsat_column = .false. Lcalipso_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif if (any(cospgridIN%land .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%land contains values out of range' Lrttov_subcolumn = .false. Lcalipso_column = .false. Lparasol_column = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%parasolGrid_refl)) cospOUT%parasolGrid_refl(:,:) = R_UNDEF endif if (any(cospgridIN%skt .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%skt contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF endif ! RTTOV Inputs if (cospgridIN%zenang .lt. -90. .OR. cospgridIN%zenang .gt. 90) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%zenang contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (cospgridIN%co2 .lt. 0) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%co2 contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (cospgridIN%ch4 .lt. 0) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%ch4 contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (cospgridIN%n2o .lt. 0) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%n2o contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (cospgridIN%co.lt. 0) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%co contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (any(cospgridIN%o3 .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%o3 contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (any(cospgridIN%emis_sfc .lt. 0. .OR. cospgridIN%emis_sfc .gt. 1)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospgridIN%emis_sfc contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (any(cospgridIN%u_sfc .lt. -100. .OR. cospgridIN%u_sfc .gt. 100.)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%u_sfc contains values out of range' if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF Lrttov_subcolumn = .false. endif if (any(cospgridIN%v_sfc .lt. -100. .OR. cospgridIN%v_sfc .gt. 100.)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%v_sfc contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif if (any(cospgridIN%lat .lt. -90 .OR. cospgridIN%lat .gt. 90)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%lat contains values out of range' Lrttov_subcolumn = .false. if (associated(cospOUT%rttov_tbs)) cospOUT%rttov_tbs(:,:) = R_UNDEF endif ! COSP_INPUTS if (cospIN%emsfc_lw .lt. 0. .OR. cospIN%emsfc_lw .gt. 1.) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%emsfc_lw contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF endif if (any(cospIN%tau_067 .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%tau_067 contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. Lmisr_subcolumn = .false. Lmisr_column = .false. Lmodis_subcolumn = .false. Lmodis_column = .false. if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_fq)) cospOUT%misr_fq(:,:,:) = R_UNDEF if (associated(cospOUT%misr_dist_model_layertops)) cospOUT%misr_dist_model_layertops(:,:) = R_UNDEF if (associated(cospOUT%misr_meanztop)) cospOUT%misr_meanztop(:) = R_UNDEF if (associated(cospOUT%misr_cldarea)) cospOUT%misr_cldarea(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffICE)) & cospOUT%modis_Optical_Thickness_vs_ReffICE(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffLIQ)) & cospOUT%modis_Optical_Thickness_vs_ReffLIQ(:,:,:) = R_UNDEF endif if (any(cospIN%emiss_11 .lt. 0. .OR. cospIN%emiss_11 .gt. 1)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%emiss_11 contains values out of range' Lisccp_subcolumn = .false. Lisccp_column = .false. if (associated(cospOUT%isccp_totalcldarea)) cospOUT%isccp_totalcldarea(:) = R_UNDEF if (associated(cospOUT%isccp_meantb)) cospOUT%isccp_meantb(:) = R_UNDEF if (associated(cospOUT%isccp_meantbclr)) cospOUT%isccp_meantbclr(:) = R_UNDEF if (associated(cospOUT%isccp_meanptop)) cospOUT%isccp_meanptop(:) = R_UNDEF if (associated(cospOUT%isccp_meantaucld)) cospOUT%isccp_meantaucld(:) = R_UNDEF if (associated(cospOUT%isccp_meanalbedocld)) cospOUT%isccp_meanalbedocld(:) = R_UNDEF if (associated(cospOUT%isccp_boxtau)) cospOUT%isccp_boxtau(:,:) = R_UNDEF if (associated(cospOUT%isccp_boxptop)) cospOUT%isccp_boxptop(:,:) = R_UNDEF if (associated(cospOUT%isccp_fq)) cospOUT%isccp_fq(:,:,:) = R_UNDEF endif if (any(cospIN%asym .lt. -1. .OR. cospIN%asym .gt. 1)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%asym contains values out of range' Lmodis_subcolumn = .false. Lmodis_column = .false. if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffICE)) & cospOUT%modis_Optical_Thickness_vs_ReffICE(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffLIQ)) & cospOUT%modis_Optical_Thickness_vs_ReffLIQ(:,:,:) = R_UNDEF endif if (any(cospIN%ss_alb .lt. 0 .OR. cospIN%ss_alb .gt. 1)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%ss_alb contains values out of range' Lmodis_subcolumn = .false. Lmodis_column = .false. if (associated(cospOUT%modis_Cloud_Fraction_Total_Mean)) & cospOUT%modis_Cloud_Fraction_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Water_Mean)) & cospOUT%modis_Cloud_Fraction_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Ice_Mean)) & cospOUT%modis_Cloud_Fraction_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_High_Mean)) & cospOUT%modis_Cloud_Fraction_High_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Mid_Mean)) & cospOUT%modis_Cloud_Fraction_Mid_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Fraction_Low_Mean)) & cospOUT%modis_Cloud_Fraction_Low_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_Mean)) & cospOUT%modis_Optical_Thickness_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_Mean)) & cospOUT%modis_Optical_Thickness_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_Mean)) & cospOUT%modis_Optical_Thickness_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Total_LogMean)) & cospOUT%modis_Optical_Thickness_Total_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Water_LogMean)) & cospOUT%modis_Optical_Thickness_Water_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_Ice_LogMean)) & cospOUT%modis_Optical_Thickness_Ice_LogMean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Water_Mean)) & cospOUT%modis_Cloud_Particle_Size_Water_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Particle_Size_Ice_Mean)) & cospOUT%modis_Cloud_Particle_Size_Ice_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Cloud_Top_Pressure_Total_Mean)) & cospOUT%modis_Cloud_Top_Pressure_Total_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Liquid_Water_Path_Mean)) & cospOUT%modis_Liquid_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Ice_Water_Path_Mean)) & cospOUT%modis_Ice_Water_Path_Mean(:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffICE)) & cospOUT%modis_Optical_Thickness_vs_ReffICE(:,:,:) = R_UNDEF if (associated(cospOUT%modis_Optical_Thickness_vs_ReffLIQ)) & cospOUT%modis_Optical_Thickness_vs_ReffLIQ(:,:,:) = R_UNDEF endif if (any(cospIN%betatot .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%betatot contains values out of range' Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%betatot_liq .lt. 0)) then nError=nError+1 errorMessage(nError) = ('ERROR: COSP input variable: cospIN%betatot_liq contains values out of range') Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%betatot_ice .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%betatot_ice contains values out of range' Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%beta_mol .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%beta_mol contains values out of range' Lcalipso_subcolumn = .false. Lcalipso_column = .false. Lcloudsat_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif if (any(cospIN%tautot .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%tautot contains values out of range' Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%tautot_liq .lt. 0)) then nError=nError+1 errorMessage(nError) = ('ERROR: COSP input variable: cospIN%tautot_liq contains values out of range') Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%tautot_ice .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%tautot_ice contains values out of range' Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%tau_mol .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%tau_mol contains values out of range' Lcalipso_subcolumn = .false. Lcalipso_column = .false. if (associated(cospOUT%calipso_cfad_sr)) cospOUT%calipso_cfad_sr(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcld)) cospOUT%calipso_lidarcld(:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldphase)) cospOUT%calipso_lidarcldphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayer)) cospOUT%calipso_cldlayer(:,:) = R_UNDEF if (associated(cospOUT%calipso_cldlayerphase)) cospOUT%calipso_cldlayerphase(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_lidarcldtmp)) cospOUT%calipso_lidarcldtmp(:,:,:) = R_UNDEF if (associated(cospOUT%calipso_srbval)) cospOUT%calipso_srbval(:) = R_UNDEF endif if (any(cospIN%tautot_S_liq .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%tautot_S_liq contains values out of range' Lparasol_subcolumn = .false. Lparasol_column = .false. if (associated(cospOUT%parasolPix_refl)) cospOUT%parasolPix_refl(:,:,:) = R_UNDEF if (associated(cospOUT%parasolGrid_refl)) cospOUT%parasolGrid_refl(:,:) = R_UNDEF endif if (any(cospIN%tautot_S_ice .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%tautot_S_ice contains values out of range' Lparasol_subcolumn = .false. Lparasol_column = .false. if (associated(cospOUT%parasolPix_refl)) cospOUT%parasolPix_refl(:,:,:) = R_UNDEF if (associated(cospOUT%parasolGrid_refl)) cospOUT%parasolGrid_refl(:,:) = R_UNDEF endif if (any(cospIN%z_vol_cloudsat .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%z_vol_cloudsat contains values out of range' Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_Ze_tot)) cospOUT%cloudsat_Ze_tot(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif if (any(cospIN%kr_vol_cloudsat .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%kr_vol_cloudsat contains values out of range' Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_Ze_tot)) cospOUT%cloudsat_Ze_tot(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif if (any(cospIN%g_vol_cloudsat .lt. 0)) then nError=nError+1 errorMessage(nError) = 'ERROR: COSP input variable: cospIN%g_vol_cloudsat contains values out of range' Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. Lradar_lidar_tcc = .false. Llidar_only_freq_cloud = .false. if (associated(cospOUT%cloudsat_cfad_ze)) cospOUT%cloudsat_cfad_ze(:,:,:) = R_UNDEF if (associated(cospOUT%cloudsat_Ze_tot)) cospOUT%cloudsat_Ze_tot(:,:,:) = R_UNDEF if (associated(cospOUT%lidar_only_freq_cloud)) cospOUT%lidar_only_freq_cloud(:,:) = R_UNDEF if (associated(cospOUT%radar_lidar_tcc)) cospOUT%radar_lidar_tcc(:) = R_UNDEF endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Part 2: Check input fields array size for consistency. This needs to be done for each ! simulator !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! ISCCP if (size(cospIN%frac_out,1) .ne. cospIN%Npoints .OR. & size(cospIN%tau_067,1) .ne. cospIN%Npoints .OR. & size(cospIN%emiss_11,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%skt) .ne. cospIN%Npoints .OR. & size(cospgridIN%qv,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%at,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%phalf,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%sunlit) .ne. cospIN%Npoints .OR. & size(cospgridIN%pfull,1) .ne. cospIN%Npoints) then Lisccp_subcolumn = .false. Lisccp_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(isccp_simulator): The number of points in the input fields are inconsistent' endif if (size(cospIN%frac_out,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%tau_067,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%emiss_11,2) .ne. cospIN%Ncolumns) then Lisccp_subcolumn = .false. Lisccp_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(isccp_simulator): The number of sub-columns in the input fields are inconsistent' endif if (size(cospIN%frac_out,3) .ne. cospIN%Nlevels .OR. & size(cospIN%tau_067,3) .ne. cospIN%Nlevels .OR. & size(cospIN%emiss_11,3) .ne. cospIN%Nlevels .OR. & size(cospgridIN%qv,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%at,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%pfull,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%phalf,2) .ne. cospIN%Nlevels+1) then Lisccp_subcolumn = .false. Lisccp_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(isccp_simulator): The number of levels in the input fields are inconsistent' endif ! MISR if (size(cospIN%tau_067,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%sunlit) .ne. cospIN%Npoints .OR. & size(cospgridIN%hgt_matrix,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%at,1) .ne. cospIN%Npoints) then Lmisr_subcolumn = .false. Lmisr_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(misr_simulator): The number of points in the input fields are inconsistent' endif if (size(cospIN%tau_067,2) .ne. cospIN%Ncolumns) then Lmisr_subcolumn = .false. Lmisr_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(misr_simulator): The number of sub-columns in the input fields are inconsistent' endif if (size(cospIN%tau_067,3) .ne. cospIN%Nlevels .OR. & size(cospgridIN%hgt_matrix,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%at,2) .ne. cospIN%Nlevels) then Lmisr_subcolumn = .false. Lmisr_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(misr_simulator): The number of levels in the input fields are inconsistent' endif ! MODIS if (size(cospIN%fracLiq,1) .ne. cospIN%Npoints .OR. & size(cospIN%tau_067,1) .ne. cospIN%Npoints .OR. & size(cospIN%asym,1) .ne. cospIN%Npoints .OR. & size(cospIN%ss_alb,1) .ne. cospIN%Npoints) then Lmodis_subcolumn = .false. Lmodis_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(modis_simulator): The number of points in the input fields are inconsistent' endif if (size(cospIN%fracLiq,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%tau_067,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%asym,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%ss_alb,2) .ne. cospIN%Ncolumns) then Lmodis_subcolumn = .false. Lmodis_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(modis_simulator): The number of sub-columns in the input fields are inconsistent' endif if (size(cospIN%fracLiq,3) .ne. cospIN%Nlevels .OR. & size(cospIN%tau_067,3) .ne. cospIN%Nlevels .OR. & size(cospIN%asym,3) .ne. cospIN%Nlevels .OR. & size(cospIN%ss_alb,3) .ne. cospIN%Nlevels) then Lmodis_subcolumn = .false. Lmodis_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(modis_simulator): The number of levels in the input fields are inconsistent' endif ! CLOUDSAT if (size(cospIN%z_vol_cloudsat,1) .ne. cospIN%Npoints .OR. & size(cospIN%kr_vol_cloudsat,1) .ne. cospIN%Npoints .OR. & size(cospIN%g_vol_cloudsat,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%hgt_matrix,1) .ne. cospIN%Npoints) then Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(cloudsat_simulator): The number of points in the input fields are inconsistent' endif if (size(cospIN%z_vol_cloudsat,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%kr_vol_cloudsat,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%g_vol_cloudsat,2) .ne. cospIN%Ncolumns) then Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(cloudsat_simulator): The number of sub-columns in the input fields are inconsistent' endif if (size(cospIN%z_vol_cloudsat,3) .ne. cospIN%Nlevels .OR. & size(cospIN%kr_vol_cloudsat,3) .ne. cospIN%Nlevels .OR. & size(cospIN%g_vol_cloudsat,3) .ne. cospIN%Nlevels .OR. & size(cospgridIN%hgt_matrix,2) .ne. cospIN%Nlevels) then Lcloudsat_subcolumn = .false. Lcloudsat_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(cloudsat_simulator): The number of levels in the input fields are inconsistent' endif ! CALIPSO if (size(cospIN%beta_mol,1) .ne. cospIN%Npoints .OR. & size(cospIN%betatot,1) .ne. cospIN%Npoints .OR. & size(cospIN%betatot_liq,1) .ne. cospIN%Npoints .OR. & size(cospIN%betatot_ice,1) .ne. cospIN%Npoints .OR. & size(cospIN%tau_mol,1) .ne. cospIN%Npoints .OR. & size(cospIN%tautot,1) .ne. cospIN%Npoints .OR. & size(cospIN%tautot_liq,1) .ne. cospIN%Npoints .OR. & size(cospIN%tautot_ice,1) .ne. cospIN%Npoints) then Lcalipso_subcolumn = .false. Lcalipso_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(calipso_simulator): The number of points in the input fields are inconsistent' endif if (size(cospIN%betatot,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%betatot_liq,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%betatot_ice,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%tautot,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%tautot_liq,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%tautot_ice,2) .ne. cospIN%Ncolumns) then Lcalipso_subcolumn = .false. Lcalipso_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(calipso_simulator): The number of sub-columns in the input fields are inconsistent' endif if (size(cospIN%beta_mol,2) .ne. cospIN%Nlevels .OR. & size(cospIN%betatot,3) .ne. cospIN%Nlevels .OR. & size(cospIN%betatot_liq,3) .ne. cospIN%Nlevels .OR. & size(cospIN%betatot_ice,3) .ne. cospIN%Nlevels .OR. & size(cospIN%tau_mol,2) .ne. cospIN%Nlevels .OR. & size(cospIN%tautot,3) .ne. cospIN%Nlevels .OR. & size(cospIN%tautot_liq,3) .ne. cospIN%Nlevels .OR. & size(cospIN%tautot_ice,3) .ne. cospIN%Nlevels) then Lcalipso_subcolumn = .false. Lcalipso_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(calipso_simulator): The number of levels in the input fields are inconsistent' endif ! PARASOL if (size(cospIN%tautot_S_liq,1) .ne. cospIN%Npoints .OR. & size(cospIN%tautot_S_ice,1) .ne. cospIN%Npoints) then Lparasol_subcolumn = .false. Lparasol_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(parasol_simulator): The number of points in the input fields are inconsistent' endif if (size(cospIN%tautot_S_liq,2) .ne. cospIN%Ncolumns .OR. & size(cospIN%tautot_S_ice,2) .ne. cospIN%Ncolumns) then Lparasol_subcolumn = .false. Lparasol_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(parasol_simulator): The number of levels in the input fields are inconsistent' endif ! RTTOV if (size(cospgridIN%pfull,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%at,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%qv,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%hgt_matrix_half,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%u_sfc) .ne. cospIN%Npoints .OR. & size(cospgridIN%v_sfc) .ne. cospIN%Npoints .OR. & size(cospgridIN%skt) .ne. cospIN%Npoints .OR. & size(cospgridIN%phalf,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%qv,1) .ne. cospIN%Npoints .OR. & size(cospgridIN%land) .ne. cospIN%Npoints .OR. & size(cospgridIN%lat) .ne. cospIN%Npoints) then Lrttov_subcolumn = .false. Lrttov_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(rttov_simulator): The number of points in the input fields are inconsistent' endif if (size(cospgridIN%pfull,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%at,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%qv,2) .ne. cospIN%Nlevels .OR. & size(cospgridIN%hgt_matrix_half,2) .ne. cospIN%Nlevels+1 .OR. & size(cospgridIN%phalf,2) .ne. cospIN%Nlevels+1 .OR. & size(cospgridIN%qv,2) .ne. cospIN%Nlevels) then Lrttov_subcolumn = .false. Lrttov_column = .false. nError=nError+1 errorMessage(nError) = 'ERROR(rttov_simulator): The number of levels in the input fields are inconsistent' endif end subroutine cosp_errorCheck !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! END MODULE !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% END MODULE MOD_COSP