! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 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 ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% #include "cosp_defs.h" MODULE MOD_COSP_INTERFACE_v1p4 use COSP_KINDS, only: wp,dp use cosp_phys_constants, only: amw,amd,amO3,amCO2,amCH4,amN2O,amCO use MOD_COSP, only: cosp_init,cosp_outputs,cosp_optical_inputs, & cosp_column_inputs,cosp_simulator,linitialization use mod_cosp_config, only: RTTOV_MAX_CHANNELS,N_HYDRO,numMODISTauBins,modis_histTau,& modis_histTauEdges,modis_histTauCenters,ntau,ntauV1p4, & tau_binBounds,tau_binEdges,tau_binCenters,R_UNDEF, & tau_binBoundsV1p4,tau_binEdgesV1p4,tau_binCentersV1p4, & numMISRHgtBins,SR_BINS,LIDAR_NCAT,LIDAR_NTEMP,DBZE_BINS, & numMODISReffIceBins, numMODISPresBins,PARASOL_NREFL, & numMODISReffLiqBins,vgrid_zl,vgrid_zu,vgrid_z, & numISCCPTauBins,numISCCPPresBins,numMISRTauBins use mod_quickbeam_optics,only: size_distribution,hydro_class_init,quickbeam_optics_init,& quickbeam_optics use cosp_optics, only: cosp_simulator_optics,lidar_optics,modis_optics, & modis_optics_partition use quickbeam, only: maxhclass,nRe_types,nd,mt_ntt,radar_cfg use mod_rng, only: rng_state, init_rng use mod_scops, only: scops use mod_prec_scops, only: prec_scops use mod_cosp_utils, only: cosp_precip_mxratio implicit none character(len=120),parameter :: & RADAR_SIM_LUT_DIRECTORY = './' logical,parameter :: & RADAR_SIM_LOAD_scale_LUTs_flag = .false., & RADAR_SIM_UPDATE_scale_LUTs_flag = .false. ! Indices to address arrays of LS and CONV hydrometeors integer,parameter :: & I_LSCLIQ = 1, & ! Large-scale (stratiform) liquid I_LSCICE = 2, & ! Large-scale (stratiform) ice I_LSRAIN = 3, & ! Large-scale (stratiform) rain I_LSSNOW = 4, & ! Large-scale (stratiform) snow I_CVCLIQ = 5, & ! Convective liquid I_CVCICE = 6, & ! Convective ice I_CVRAIN = 7, & ! Convective rain I_CVSNOW = 8, & ! Convective snow I_LSGRPL = 9 ! Large-scale (stratiform) groupel ! Stratiform and convective clouds in frac_out. integer, parameter :: & I_LSC = 1, & ! Large-scale clouds I_CVC = 2 ! Convective clouds ! Microphysical settings for the precipitation flux to mixing ratio conversion real(wp),parameter,dimension(N_HYDRO) :: & ! LSL LSI LSR LSS CVL CVI CVR CVS LSG N_ax = (/-1., -1., 8.e6, 3.e6, -1., -1., 8.e6, 3.e6, 4.e6/),& N_bx = (/-1., -1., 0.0, 0.0, -1., -1., 0.0, 0.0, 0.0/),& alpha_x = (/-1., -1., 0.0, 0.0, -1., -1., 0.0, 0.0, 0.0/),& c_x = (/-1., -1., 842.0, 4.84, -1., -1., 842.0, 4.84, 94.5/),& d_x = (/-1., -1., 0.8, 0.25, -1., -1., 0.8, 0.25, 0.5/),& g_x = (/-1., -1., 0.5, 0.5, -1., -1., 0.5, 0.5, 0.5/),& a_x = (/-1., -1., 524.0, 52.36, -1., -1., 524.0, 52.36, 209.44/),& b_x = (/-1., -1., 3.0, 3.0, -1., -1., 3.0, 3.0, 3.0/),& gamma_1 = (/-1., -1., 17.83725, 8.284701, -1., -1., 17.83725, 8.284701, 11.63230/),& gamma_2 = (/-1., -1., 6.0, 6.0, -1., -1., 6.0, 6.0, 6.0/),& gamma_3 = (/-1., -1., 2.0, 2.0, -1., -1., 2.0, 2.0, 2.0/),& gamma_4 = (/-1., -1., 6.0, 6.0, -1., -1., 6.0, 6.0, 6.0/) ! Initialization fields type(size_distribution) :: & sd ! Hydrometeor description type(radar_cfg) :: & rcfg_cloudsat ! Radar configuration !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE COSP_CONFIG !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE COSP_CONFIG logical :: & Lstats, & ! Control for L3 stats output Lwrite_output, & ! Control for output Ltoffset, & ! Time difference between each profile and the value ! recorded in varaible time. Lradar_sim, & ! Radar simulator on/off switch Llidar_sim, & ! LIDAR simulator on/off switch Lisccp_sim, & ! ISCCP simulator on/off switch Lmodis_sim, & ! MODIS simulatoe on/off switch Lmisr_sim, & ! MISR simulator on/off switch Lrttov_sim, & ! RTTOV simulator on/off switch Lparasol_sim, & ! PARASOL simulator on/off switch Lpctisccp, & ! ISCCP mean cloud top pressure Lclisccp, & ! ISCCP cloud area fraction Lboxptopisccp, & ! ISCCP CTP in each column Lboxtauisccp, & ! ISCCP optical epth in each column Ltauisccp, & ! ISCCP mean optical depth Lcltisccp, & ! ISCCP total cloud fraction Lmeantbisccp, & ! ISCCP mean all-sky 10.5micron brightness temperature Lmeantbclrisccp, & ! ISCCP mean clear-sky 10.5micron brightness temperature Lalbisccp, & ! ISCCP mean cloud albedo LcfadDbze94, & ! CLOUDSAT radar reflectivity CFAD Ldbze94, & ! CLOUDSAT radar reflectivity LparasolRefl, & ! PARASOL reflectance Latb532, & ! CALIPSO attenuated total backscatter (532nm) LlidarBetaMol532, & ! CALIPSO molecular backscatter (532nm) LcfadLidarsr532, & ! CALIPSO scattering ratio CFAD Lclcalipso2, & ! CALIPSO cloud fraction undetected by cloudsat Lclcalipso, & ! CALIPSO cloud area fraction Lclhcalipso, & ! CALIPSO high-level cloud fraction Lcllcalipso, & ! CALIPSO low-level cloud fraction Lclmcalipso, & ! CALIPSO mid-level cloud fraction Lcltcalipso, & ! CALIPSO total cloud fraction Lcltlidarradar, & ! CALIPSO-CLOUDSAT total cloud fraction Lclcalipsoliq, & ! CALIPSO liquid cloud area fraction Lclcalipsoice, & ! CALIPSO ice cloud area fraction Lclcalipsoun, & ! CALIPSO undetected cloud area fraction Lclcalipsotmp, & ! CALIPSO undetected cloud area fraction Lclcalipsotmpliq, & ! CALIPSO liquid cloud area fraction Lclcalipsotmpice, & ! CALIPSO ice cloud area fraction Lclcalipsotmpun, & ! CALIPSO undetected cloud area fraction Lcltcalipsoliq, & ! CALIPSO liquid total cloud fraction Lcltcalipsoice, & ! CALIPSO ice total cloud fraction Lcltcalipsoun, & ! CALIPSO undetected total cloud fraction Lclhcalipsoliq, & ! CALIPSO high-level liquid cloud fraction Lclhcalipsoice, & ! CALIPSO high-level ice cloud fraction Lclhcalipsoun, & ! CALIPSO high-level undetected cloud fraction Lclmcalipsoliq, & ! CALIPSO mid-level liquid cloud fraction Lclmcalipsoice, & ! CALIPSO mid-level ice cloud fraction Lclmcalipsoun, & ! CALIPSO mid-level undetected cloud fraction Lcllcalipsoliq, & ! CALIPSO low-level liquid cloud fraction Lcllcalipsoice, & ! CALIPSO low-level ice cloud fraction Lcllcalipsoun, & ! CALIPSO low-level undetected cloud fraction Lcltmodis, & ! MODIS total cloud fraction Lclwmodis, & ! MODIS liquid cloud fraction Lclimodis, & ! MODIS ice cloud fraction Lclhmodis, & ! MODIS high-level cloud fraction Lclmmodis, & ! MODIS mid-level cloud fraction Lcllmodis, & ! MODIS low-level cloud fraction Ltautmodis, & ! MODIS total cloud optical thicknes Ltauwmodis, & ! MODIS liquid optical thickness Ltauimodis, & ! MODIS ice optical thickness Ltautlogmodis, & ! MODIS total cloud optical thickness (log10 mean) Ltauwlogmodis, & ! MODIS liquid optical thickness (log10 mean) Ltauilogmodis, & ! MODIS ice optical thickness (log10 mean) Lreffclwmodis, & ! MODIS liquid cloud particle size Lreffclimodis, & ! MODIS ice particle size Lpctmodis, & ! MODIS cloud top pressure Llwpmodis, & ! MODIS cloud ice water path Liwpmodis, & ! MODIS cloud liquid water path Lclmodis, & ! MODIS cloud area fraction LclMISR, & ! MISR cloud fraction Lfracout, & ! SCOPS Subcolumn output Ltbrttov ! RTTOV mean clear-sky brightness temperature ! character(len=32),dimension(:),allocatable :: out_list character(len=32) :: out_list(78) END TYPE COSP_CONFIG !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_vgrid !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE COSP_VGRID logical :: & use_vgrid, & ! Logical flag that indicates change of grid csat_vgrid ! Flag for Cloudsat grid integer :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nlvgrid ! Number of levels of new grid real(wp), dimension(:), pointer :: & z, & ! Height of new level (Nlvgrid) zl, & ! Lower boundaries of new levels (Nlvgrid) zu, & ! Upper boundaries of new levels (Nlvgrid) mz, & ! Height of model levels (Nlevels) mzl, & ! Lower boundaries of model levels (Nlevels) mzu ! Upper boundaries of model levels (Nlevels) END TYPE COSP_VGRID !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE COSP_SUBGRID !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE COSP_SUBGRID integer :: & Npoints, & ! Number of gridpoints Ncolumns, & ! Number of columns Nlevels, & ! Number of levels Nhydro ! Number of hydrometeor types real(wp),dimension(:,:,:),pointer :: & prec_frac, & ! Subgrid precip array (Npoints,Ncolumns,Nlevels) frac_out ! Subgrid cloud array (Npoints,Ncolumns,Nlevels) END TYPE COSP_SUBGRID ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE class_param ! With the reorganizing of COSPv2.0, this derived type ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% type class_param ! Variables used to store hydrometeor "default" properties real(dp),dimension(maxhclass) :: p1,p2,p3,dmin,dmax,apm,bpm,rho integer, dimension(maxhclass) :: dtype,col,cp,phase ! Radar properties real(dp) :: freq,k2 integer :: nhclass ! number of hydrometeor classes in use integer :: use_gas_abs, do_ray ! Defines location of radar relative to hgt_matrix. logical :: radar_at_layer_one ! If true radar is assume to be at the edge ! of the first layer, if the first layer is the ! surface than a ground-based radar. If the ! first layer is the top-of-atmosphere, then ! a space borne radar. ! Variables used to store Z scale factors character(len=240) :: scale_LUT_file_name logical :: load_scale_LUTs, update_scale_LUTs logical, dimension(maxhclass,nRe_types) :: N_scale_flag logical, dimension(maxhclass,mt_ntt,nRe_types) :: Z_scale_flag,Z_scale_added_flag real(dp),dimension(maxhclass,mt_ntt,nRe_types) :: Ze_scaled,Zr_scaled,kr_scaled real(dp),dimension(maxhclass,nd,nRe_types) :: fc, rho_eff end type class_param ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_gridbox ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE cosp_gridbox integer :: & Npoints, & ! Number of gridpoints Nlevels, & ! Number of levels Ncolumns, & ! Number of columns Nhydro, & ! Number of hydrometeors Nprmts_max_hydro, & ! Max number of parameters for hydrometeor size distribution Naero, & ! Number of aerosol species Nprmts_max_aero, & ! Max number of parameters for aerosol size distributions Npoints_it ! Max number of gridpoints to be processed in one iteration ! Time [days] double precision :: time double precision :: time_bnds(2) ! Radar ancillary info real(wp) :: & radar_freq, & ! Radar frequency [GHz] k2 ! |K|^2, -1=use frequency dependent default integer :: surface_radar, & ! surface=1, spaceborne=0 use_mie_tables, & ! use a precomputed loopup table? yes=1,no=0 use_gas_abs, & ! include gaseous absorption? yes=1,no=0 do_ray, & ! calculate/output Rayleigh refl=1, not=0 melt_lay ! melting layer model off=0, on=1 ! Structures used by radar simulator that need to be set only ONCE per ! radar configuration (e.g. freq, pointing direction) ... added by roj Feb 2008 type(class_param) :: & hp ! Structure used by radar simulator to store Ze and N scaling constants ! and other information integer :: & nsizes ! Number of discrete drop sizes (um) used to represent the distribution ! Lidar integer :: & lidar_ice_type ! Ice particle shape hypothesis in lidar calculations ! (ice_type=0 for spheres, ice_type=1 for non spherical particles) ! Radar logical :: & use_precipitation_fluxes, & ! True if precipitation fluxes are input to the ! algorithm use_reff ! True if Reff is to be used by radar (memory not ! allocated) ! Geolocation and point information (Npoints) real(wp),dimension(:),pointer :: & toffset, & ! Time offset of esch point from the value in time longitude, & ! Longitude [degrees East] latitude, & ! Latitude [deg North] land, & ! Landmask [0 - Ocean, 1 - Land] psfc, & ! Surface pressure [Pa] sunlit, & ! 1 for day points, 0 for nightime skt, & ! Skin temperature (K) u_wind, & ! Eastward wind [m s-1] v_wind ! Northward wind [m s-1] ! Gridbox information (Npoints,Nlevels) real(wp),dimension(:,:),pointer :: & zlev, & ! Height of model levels [m] zlev_half, & ! Height at half model levels [m] (Bottom of layer) dlev, & ! Depth of model levels [m] p, & ! Pressure at full model levels [Pa] ph, & ! Pressure at half model levels [Pa] T, & ! Temperature at model levels [K] q, & ! Relative humidity to water (%) sh, & ! Specific humidity to water [kg/kg] dtau_s, & ! mean 0.67 micron optical depth of stratiform clouds dtau_c, & ! mean 0.67 micron optical depth of convective clouds dem_s, & ! 10.5 micron longwave emissivity of stratiform clouds dem_c, & ! 10.5 micron longwave emissivity of convective clouds mr_ozone ! Ozone mass mixing ratio [kg/kg] ! TOTAL and CONV cloud fraction for SCOPS real(wp),dimension(:,:),pointer :: & tca, & ! Total cloud fraction cca ! Convective cloud fraction ! Precipitation fluxes on model levels real(wp),dimension(:,:),pointer :: & rain_ls, & ! Large-scale precipitation flux of rain [kg/m2.s] rain_cv, & ! Convective precipitation flux of rain [kg/m2.s] snow_ls, & ! Large-scale precipitation flux of snow [kg/m2.s] snow_cv, & ! Convective precipitation flux of snow [kg/m2.s] grpl_ls ! large-scale precipitation flux of graupel [kg/m2.s] ! Hydrometeors concentration and distribution parameters real(wp),dimension(:,:,:),pointer :: & mr_hydro ! Mixing ratio of each hydrometeor ! (Npoints,Nlevels,Nhydro) [kg/kg] real(wp),dimension(:,:),pointer :: & dist_prmts_hydro ! Distributional parameters for hydrometeors ! (Nprmts_max_hydro,Nhydro) real(wp),dimension(:,:,:),pointer :: & Reff ! Effective radius [m]. ! (Npoints,Nlevels,Nhydro) real(wp),dimension(:,:,:),pointer :: & Np ! Total Number Concentration [#/kg]. ! (Npoints,Nlevels,Nhydro) ! Aerosols concentration and distribution parameters real(wp),dimension(:,:,:),pointer :: & conc_aero ! Aerosol concentration for each species ! (Npoints,Nlevels,Naero) integer,dimension(:),pointer :: & dist_type_aero ! Particle size distribution type for each aerosol species ! (Naero) real(wp),dimension(:,:,:,:),pointer :: & dist_prmts_aero ! Distributional parameters for aerosols ! (Npoints,Nlevels,Nprmts_max_aero,Naero) ! ISCCP simulator inputs integer :: & ! ISCCP_TOP_HEIGHT ! 1 = adjust top height using both a computed infrared brightness temperature and ! the visible optical depth to adjust cloud top pressure. Note that this ! calculation is most appropriate to compare to ISCCP data during sunlit ! hours. ! 2 = do not adjust top height, that is cloud top pressure is the actual cloud ! top pressure in the model. ! 3 = adjust top height using only the computed infrared brightness temperature. ! Note that this calculation is most appropriate to compare to ISCCP IR only ! algortihm (i.e. you can compare to nighttime ISCCP data with this option) isccp_top_height, & ! ISCCP_TOP_HEIGHT_DIRECTION ! Direction for finding atmosphere pressure level with interpolated temperature ! equal to the radiance determined cloud-top temperature ! 1 = find the *lowest* altitude (highest pressure) level with interpolated ! temperature equal to the radiance determined cloud-top temperature ! 2 = find the *highest* altitude (lowest pressure) level with interpolated ! temperature equal to the radiance determined cloud-top temperature ! ONLY APPLICABLE IF top_height EQUALS 1 or 3 ! 1 = default setting, and matches all versions of ISCCP simulator with versions ! numbers 3.5.1 and lower; 2 = experimental setting isccp_top_height_direction, & ! Overlap type (1=max, 2=rand, 3=max/rand) isccp_overlap real(wp) :: & isccp_emsfc_lw ! 10.5 micron emissivity of surface (fraction) ! RTTOV inputs/options integer :: & plat, & ! Satellite platform sat, & ! Satellite inst, & ! Instrument Nchan ! Number of channels to be computed integer, dimension(:), pointer :: & Ichan ! Channel numbers real(wp),dimension(:), pointer :: & Surfem ! Surface emissivity real(wp) :: & ZenAng, & ! Satellite Zenith Angles co2, & ! CO2 mixing ratio ch4, & ! CH4 mixing ratio n2o, & ! N2O mixing ratio co ! CO mixing ratio END TYPE cosp_gridbox ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_modis ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% type cosp_modis integer,pointer :: & ! Npoints ! Number of gridpoints real(wp),pointer,dimension(:) :: & ! Cloud_Fraction_Total_Mean, & ! L3 MODIS retrieved cloud fraction (total) Cloud_Fraction_Water_Mean, & ! L3 MODIS retrieved cloud fraction (liq) Cloud_Fraction_Ice_Mean, & ! L3 MODIS retrieved cloud fraction (ice) Cloud_Fraction_High_Mean, & ! L3 MODIS retrieved cloud fraction (high) Cloud_Fraction_Mid_Mean, & ! L3 MODIS retrieved cloud fraction (middle) Cloud_Fraction_Low_Mean, & ! L3 MODIS retrieved cloud fraction (low ) Optical_Thickness_Total_Mean, & ! L3 MODIS retrieved optical thickness (tot) Optical_Thickness_Water_Mean, & ! L3 MODIS retrieved optical thickness (liq) Optical_Thickness_Ice_Mean, & ! L3 MODIS retrieved optical thickness (ice) Optical_Thickness_Total_LogMean, & ! L3 MODIS retrieved log10 optical thickness Optical_Thickness_Water_LogMean, & ! L3 MODIS retrieved log10 optical thickness Optical_Thickness_Ice_LogMean, & ! L3 MODIS retrieved log10 optical thickness Cloud_Particle_Size_Water_Mean, & ! L3 MODIS retrieved particle size (liquid) Cloud_Particle_Size_Ice_Mean, & ! L3 MODIS retrieved particle size (ice) Cloud_Top_Pressure_Total_Mean, & ! L3 MODIS retrieved cloud top pressure Liquid_Water_Path_Mean, & ! L3 MODIS retrieved liquid water path Ice_Water_Path_Mean ! L3 MODIS retrieved ice water path real(wp),pointer,dimension(:,:,:) :: & Optical_Thickness_vs_Cloud_Top_Pressure, & ! Tau/Pressure joint histogram Optical_Thickness_vs_ReffICE, & ! Tau/ReffICE joint histogram Optical_Thickness_vs_ReffLIQ ! Tau/ReffLIQ joint histogram end type cosp_modis ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_misr ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE COSP_MISR integer,pointer :: & Npoints, & ! Number of gridpoints Ntau, & ! Number of tau intervals Nlevels ! Number of cth levels real(wp),dimension(:,:,:),pointer :: & ! fq_MISR ! Fraction of the model grid box covered by each of the MISR ! cloud types real(wp),dimension(:,:),pointer :: & ! MISR_dist_model_layertops ! real(wp),dimension(:),pointer :: & ! MISR_meanztop, & ! Mean MISR cloud top height MISR_cldarea ! Mean MISR cloud cover area END TYPE COSP_MISR ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_rttov ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE COSP_RTTOV ! Dimensions integer,pointer :: & Npoints, & ! Number of gridpoints Nchan ! Number of channels ! Brightness temperatures (Npoints,Nchan) real(wp),pointer :: tbs(:,:) END TYPE COSP_RTTOV !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_isccp !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% TYPE COSP_ISCCP integer,pointer ::& Npoints, & ! Number of gridpoints. Ncolumns, & ! Number of columns. Nlevels ! Number of levels. real(wp),dimension(:),pointer :: & totalcldarea, & ! The fraction of model grid box columns with cloud somewhere in ! them. meantb, & ! Mean all-sky 10.5 micron brightness temperature. meantbclr, & ! Mean clear-sky 10.5 micron brightness temperature. meanptop, & ! Mean cloud top pressure (mb). meantaucld, & ! Mean optical thickness. meanalbedocld ! Mean cloud albedo. real(wp),dimension(:,:),pointer ::& boxtau, & ! Optical thickness in each column . boxptop ! Cloud top pressure (mb) in each column. real(wp),dimension(:,:,:),pointer :: & fq_isccp ! The fraction of the model grid box covered by each of the 49 ! ISCCP D level cloud types. END TYPE COSP_ISCCP !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_sglidar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% type cosp_sglidar integer,pointer :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nhydro, & ! Number of hydrometeors Nrefl ! Number of parasol reflectances real(wp),dimension(:,:),pointer :: & beta_mol, & ! Molecular backscatter temp_tot real(wp),dimension(:,:,:),pointer :: & betaperp_tot, & ! Total backscattered signal beta_tot, & ! Total backscattered signal tau_tot, & ! Optical thickness integrated from top to level z refl ! PARASOL reflectances end type cosp_sglidar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_lidarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% type cosp_lidarstats integer,pointer :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nhydro, & ! Number of hydrometeors Nrefl ! Number of parasol reflectances real(wp), dimension(:,:,:),pointer :: & lidarcldphase, & ! 3D "lidar" phase cloud fraction cldlayerphase, & ! low, mid, high-level lidar phase cloud cover lidarcldtmp, & ! 3D "lidar" phase cloud temperature cfad_sr ! CFAD of scattering ratio real(wp), dimension(:,:),pointer :: & lidarcld, & ! 3D "lidar" cloud fraction cldlayer, & ! low, mid, high-level, total lidar cloud cover parasolrefl real(wp), dimension(:),pointer :: & srbval ! SR bins in cfad_sr end type cosp_lidarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_sgradar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% type cosp_sgradar ! Dimensions integer,pointer :: & Npoints, & ! Number of gridpoints Ncolumns, & ! Number of columns Nlevels, & ! Number of levels Nhydro ! Number of hydrometeors real(wp),dimension(:,:),pointer :: & att_gas ! 2-way attenuation by gases [dBZ] (Npoints,Nlevels) real(wp),dimension(:,:,:),pointer :: & Ze_tot ! Effective reflectivity factor (Npoints,Ncolumns,Nlevels) end type cosp_sgradar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! TYPE cosp_radarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% type cosp_radarstats integer,pointer :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nhydro ! Number of hydrometeors real(wp), dimension(:,:,:), pointer :: & cfad_ze ! Ze CFAD(Npoints,dBZe_bins,Nlevels) real(wp),dimension(:),pointer :: & radar_lidar_tcc ! Radar&lidar total cloud amount, grid-box scale (Npoints) real(wp), dimension(:,:),pointer :: & lidar_only_freq_cloud !(Npoints,Nlevels) end type cosp_radarstats contains !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE COSP_INTERFACE (v1.4) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine cosp_interface_v1p4(overlap,Ncolumns,cfg,vgrid,gbx,sgx,sgradar,sglidar, & isccp,misr,modis,rttov,stradar,stlidar) ! Inputs integer, intent(in) :: overlap ! Overlap type in SCOPS: 1=max, ! 2=rand, 3=max/rand integer, intent(in) :: Ncolumns ! Number of columns type(cosp_config), intent(in) :: cfg ! Configuration options type(cosp_vgrid),target,intent(in) :: vgrid ! Information on vertical grid of ! stats type(cosp_subgrid), intent(inout) :: sgx ! Subgrid info type(cosp_sgradar), intent(inout) :: sgradar ! Output from radar simulator (pixel) type(cosp_sglidar), intent(inout) :: sglidar ! Output from lidar simulator (pixel) type(cosp_isccp), intent(inout) :: isccp ! Output from ISCCP simulator type(cosp_misr), intent(inout) :: misr ! Output from MISR simulator type(cosp_modis), intent(inout) :: modis ! Output from MODIS simulator type(cosp_rttov), intent(inout) :: rttov ! Output from RTTOV type(cosp_radarstats), intent(inout) :: stradar ! Summary statistics from cloudsat ! simulator (gridbox) type(cosp_lidarstats), intent(inout) :: stlidar ! Output from LIDAR simulator (gridbox) type(cosp_gridbox),intent(inout),target :: gbx ! COSP gridbox type from v1.4 ! Shares memory with new type ! Outputs from COSP2 type(cosp_outputs),target :: cospOUT ! NEW derived type output that contains all ! simulator information ! Local variables integer :: i integer :: & num_chunks, & ! Number of iterations to make start_idx, & ! Starting index when looping over points end_idx, & ! Ending index when looping over points Nptsperit ! Number of points for current iteration logical :: & lsingle=.true., & ! True if using MMF_v3_single_moment CLOUDSAT microphysical scheme (default) ldouble=.false. ! True if using MMF_v3.5_two_moment CLOUDSAT microphysical scheme type(cosp_optical_inputs) :: & cospIN ! COSP optical (or derived?) fields needed by simulators type(cosp_column_inputs) :: & cospstateIN ! COSP model fields needed by simulators character(len=256),dimension(100) :: cosp_status #ifdef MMF_V3_SINGLE_MOMENT character(len=64) :: & cloudsat_micro_scheme = 'MMF_v3_single_moment' #endif #ifdef MMF_V3p5_TWO_MOMENT character(len=64) :: & cloudsat_micro_scheme = 'MMF_v3.5_two_moment' #endif ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Initialize COSP ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Initialize MODIS optical-depth bin boundaries for joint-histogram. (defined in cosp_config.F90) if (.not. allocated(modis_histTau)) then allocate(modis_histTau(ntauV1p4+1),modis_histTauEdges(2,ntauV1p4),modis_histTauCenters(ntauV1p4)) numMODIStauBins = ntauV1p4+1 modis_histTau = tau_binBoundsV1p4 modis_histTauEdges = tau_binEdgesV1p4 modis_histTauCenters = tau_binCentersV1p4 endif print*,'allocated(vgrid_zl)',allocated(vgrid_zl) if (.not. allocated(vgrid_zl) .or. .not. allocated(vgrid_zu) .or. .not. allocated(vgrid_z)) then ! Initialize quickbeam_optics, also if two-moment radar microphysics scheme is wanted... if (cloudsat_micro_scheme == 'MMF_v3.5_two_moment') then ldouble = .true. lsingle = .false. endif ! Initialize the distributional parameters for hydrometeors in radar simulator call hydro_class_init(lsingle,ldouble,sd) ! Initialize COSP simulator call COSP_INIT(cfg%Lisccp_sim,cfg%Lmodis_sim,cfg%Lmisr_sim,cfg%Lradar_sim, & cfg%Llidar_sim,cfg%Lparasol_sim,cfg%Lrttov_sim,gbx%Npoints,gbx%Nlevels, & gbx%radar_freq,gbx%k2,gbx%use_gas_abs,gbx%do_ray,gbx%isccp_top_height, & gbx%isccp_top_height_direction,gbx%surface_radar,rcfg_cloudsat,gbx%Nchan, & gbx%Ichan,gbx%plat,gbx%sat,gbx%inst,vgrid%use_vgrid,vgrid%csat_vgrid, & vgrid%Nlvgrid,cloudsat_micro_scheme,cospOUT) endif ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Construct output type for cosp ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% call construct_cosp_outputs(cfg%Lpctisccp,cfg%Lclisccp,cfg%Lboxptopisccp, & cfg%Lboxtauisccp,cfg%Ltauisccp,cfg%Lcltisccp, & cfg%Lmeantbisccp,cfg%Lmeantbclrisccp,cfg%Lalbisccp, & cfg%LclMISR,cfg%Lcltmodis,cfg%Lclwmodis,cfg%Lclimodis, & cfg%Lclhmodis,cfg%Lclmmodis,cfg%Lcllmodis,cfg%Ltautmodis,& cfg%Ltauwmodis,cfg%Ltauimodis,cfg%Ltautlogmodis, & cfg%Ltauwlogmodis,cfg%Ltauilogmodis,cfg%Lreffclwmodis, & cfg%Lreffclimodis,cfg%Lpctmodis,cfg%Llwpmodis, & cfg%Liwpmodis,cfg%Lclmodis,cfg%Latb532, & cfg%LlidarBetaMol532,cfg%LcfadLidarsr532,cfg%Lclcalipso2,& cfg%Lclcalipso,cfg%Lclhcalipso,cfg%Lcllcalipso, & cfg%Lclmcalipso,cfg%Lcltcalipso,cfg%Lcltlidarradar, & cfg%Lclcalipsoliq,cfg%Lclcalipsoice,cfg%Lclcalipsoun, & cfg%Lclcalipsotmp,cfg%Lclcalipsotmpliq, & cfg%Lclcalipsotmpice,cfg%Lclcalipsotmpun, & cfg%Lcltcalipsoliq,cfg%Lcltcalipsoice,cfg%Lcltcalipsoun, & cfg%Lclhcalipsoliq,cfg%Lclhcalipsoice,cfg%Lclhcalipsoun, & cfg%Lclmcalipsoliq,cfg%Lclmcalipsoice,cfg%Lclmcalipsoun, & cfg%Lcllcalipsoliq,cfg%Lcllcalipsoice,cfg%Lcllcalipsoun, & cfg%LcfadDbze94,cfg%Ldbze94,cfg%Lparasolrefl, & cfg%Ltbrttov,gbx%Npoints,gbx%Ncolumns,gbx%Nlevels, & vgrid%Nlvgrid,gbx%Nchan,cospOUT) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Break COSP into chunks, only applicable when gbx%Npoints_it > gbx%Npoints !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% num_chunks = gbx%Npoints/gbx%Npoints_it+1 DO i=1,num_chunks !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Determine indices for "chunking" (again, if necessary) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (num_chunks .eq. 1) then start_idx = 1 end_idx = gbx%Npoints Nptsperit = gbx%Npoints else start_idx = (i-1)*gbx%Npoints_it+1 end_idx = i*gbx%Npoints_it if (end_idx .gt. gbx%Npoints) end_idx=gbx%Npoints Nptsperit = end_idx-start_idx+1 endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Allocate space !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (i .eq. 1) then call construct_cospIN(Nptsperit,gbx%ncolumns,gbx%nlevels,cospIN) call construct_cospstateIN(Nptsperit,gbx%nlevels,gbx%nchan,cospstateIN) endif if (i .eq. num_chunks) then call destroy_cospIN(cospIN) call destroy_cospstateIN(cospstateIN) call construct_cospIN(Nptsperit,gbx%ncolumns,gbx%nlevels,cospIN) call construct_cospstateIN(Nptsperit,gbx%nlevels,gbx%nchan,cospstateIN) endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Generate subcolumns and compute optical inputs to COSP. ! This subroutine essentially contains all of the pieces of code that were removed ! from the simulators during the v2.0 reconstruction. !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% call subsample_and_optics(overlap,gbx,sgx,cfg,Nptsperit,start_idx,end_idx,cospIN, & cospstateIN) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Call COSPv2.0 !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% cosp_status = COSP_SIMULATOR(cospIN, cospstateIN, cospOUT, start_idx,end_idx,.false.) enddo !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Free up memory !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% call destroy_cospIN(cospIN) call destroy_cospstateIN(cospstateIN) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Copy new output to old output types. !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! MISR if (cfg%Lmisr_sim) then if (cfg%LclMISR) misr%fq_MISR = cospOUT%misr_fq ! *NOTE* These 3 fields are not output, but were part of the v1.4.0 cosp_misr, so ! they are still computed. Should probably have a logical to control these ! outputs in cosp_config. In the meantime, only assign v1.4.0 outputs to ! v2.0 outputs IF a MISR diagnostic was requested. if (cfg%LclMISR) misr%MISR_meanztop = cospOUT%misr_meanztop if (cfg%LclMISR) misr%MISR_cldarea = cospOUT%misr_cldarea if (cfg%LclMISR) misr%MISR_dist_model_layertops = cospOUT%misr_dist_model_layertops endif ! ISCCP if (cfg%Lisccp_sim) then if (cfg%Lboxtauisccp) isccp%boxtau = cospOUT%isccp_boxtau if (cfg%Lboxptopisccp) isccp%boxptop = cospOUT%isccp_boxptop if (cfg%Lclisccp) isccp%fq_isccp = cospOUT%isccp_fq if (cfg%Lcltisccp) isccp%totalcldarea = cospOUT%isccp_totalcldarea if (cfg%Lmeantbisccp) isccp%meantb = cospOUT%isccp_meantb if (cfg%Lmeantbclrisccp) isccp%meantbclr = cospOUT%isccp_meantbclr if (cfg%Lpctisccp) isccp%meanptop = cospOUT%isccp_meanptop if (cfg%Ltauisccp) isccp%meantaucld = cospOUT%isccp_meantaucld if (cfg%Lalbisccp) isccp%meanalbedocld = cospOUT%isccp_meanalbedocld endif ! MODIS if (cfg%Lmodis_sim) then if (cfg%Lcltmodis) modis%Cloud_Fraction_Total_Mean = & cospOUT%modis_Cloud_Fraction_Total_Mean if (cfg%Lclwmodis) modis%Cloud_Fraction_Water_Mean = & cospOUT%modis_Cloud_Fraction_Water_Mean if (cfg%Lclimodis) modis%Cloud_Fraction_Ice_Mean = & cospOUT%modis_Cloud_Fraction_Ice_Mean if (cfg%Lclhmodis) modis%Cloud_Fraction_High_Mean = & cospOUT%modis_Cloud_Fraction_High_Mean if (cfg%Lclmmodis) modis%Cloud_Fraction_Mid_Mean = & cospOUT%modis_Cloud_Fraction_Mid_Mean if (cfg%Lcllmodis) modis%Cloud_Fraction_Low_Mean = & cospOUT%modis_Cloud_Fraction_Low_Mean if (cfg%Ltautmodis) modis%Optical_Thickness_Total_Mean = & cospOUT%modis_Optical_Thickness_Total_Mean if (cfg%Ltauwmodis) modis%Optical_Thickness_Water_Mean = & cospOUT%modis_Optical_Thickness_Water_Mean if (cfg%Ltauimodis) modis%Optical_Thickness_Ice_Mean = & cospOUT%modis_Optical_Thickness_Ice_Mean if (cfg%Ltautlogmodis) modis%Optical_Thickness_Total_LogMean = & cospOUT%modis_Optical_Thickness_Total_LogMean if (cfg%Ltauwlogmodis) modis%Optical_Thickness_Water_LogMean = & cospOUT%modis_Optical_Thickness_Water_LogMean if (cfg%Ltauilogmodis) modis%Optical_Thickness_Ice_LogMean = & cospOUT%modis_Optical_Thickness_Ice_LogMean if (cfg%Lreffclwmodis) modis%Cloud_Particle_Size_Water_Mean = & cospOUT%modis_Cloud_Particle_Size_Water_Mean if (cfg%Lreffclimodis) modis%Cloud_Particle_Size_Ice_Mean = & cospOUT%modis_Cloud_Particle_Size_Ice_Mean if (cfg%Lpctmodis) modis%Cloud_Top_Pressure_Total_Mean = & cospOUT%modis_Cloud_Top_Pressure_Total_Mean if (cfg%Llwpmodis) modis%Liquid_Water_Path_Mean = & cospOUT%modis_Liquid_Water_Path_Mean if (cfg%Liwpmodis) modis%Ice_Water_Path_Mean = & cospOUT%modis_Ice_Water_Path_Mean if (cfg%Lclmodis) then modis%Optical_Thickness_vs_Cloud_Top_Pressure = & cospOUT%modis_Optical_Thickness_vs_Cloud_Top_Pressure modis%Optical_Thickness_vs_ReffICE = cospOUT%modis_Optical_Thickness_vs_ReffICE modis%Optical_Thickness_vs_ReffLIQ = cospOUT%modis_Optical_Thickness_vs_ReffLIQ endif endif ! PARASOL if (cfg%Lparasol_sim) then if (cfg%Lparasolrefl) sglidar%refl = cospOUT%parasolPix_refl if (cfg%Lparasolrefl) stlidar%parasolrefl = cospOUT%parasolGrid_refl endif ! RTTOV if (cfg%Lrttov_sim) then if (cfg%Ltbrttov) rttov%tbs = cospOUT%rttov_tbs endif ! CALIPSO if (cfg%Llidar_sim) then ! *NOTE* In COSPv2.0 all outputs are ordered from TOA-2-SFC, but in COSPv1.4 this is ! not true. To maintain the outputs of v1.4, the affected fields are flipped. if (cfg%LlidarBetaMol532) then sglidar%beta_mol = cospOUT%calipso_beta_mol!(:,sglidar%Nlevels:1:-1) endif if (cfg%Latb532) then !cospOUT%calipso_beta_tot = cospOUT%calipso_beta_tot(:,:,sglidar%Nlevels:1:-1) sglidar%beta_tot = cospOUT%calipso_beta_tot endif if (cfg%LcfadLidarsr532) then stlidar%srbval = cospOUT%calipso_srbval stlidar%cfad_sr = cospOUT%calipso_cfad_sr(:,:,vgrid%Nlvgrid:1:-1) sglidar%betaperp_tot = cospOUT%calipso_betaperp_tot(:,:,sglidar%Nlevels:1:-1) endif if (cfg%Lclcalipso) then stlidar%lidarcld = cospOUT%calipso_lidarcld(:,stlidar%Nlevels:1:-1) endif if (cfg%Lclhcalipso .or. cfg%Lclmcalipso .or. cfg%Lcllcalipso .or. cfg%Lcltcalipso) then stlidar%cldlayer = cospOUT%calipso_cldlayer endif if (cfg%Lclcalipsoice .or. cfg%Lclcalipsoliq .or. cfg%Lclcalipsoun) then stlidar%lidarcldphase = cospOUT%calipso_lidarcldphase(:,vgrid%Nlvgrid:1:-1,:) endif if (cfg%Lcllcalipsoice .or. cfg%Lclmcalipsoice .or. cfg%Lclhcalipsoice .or. & cfg%Lcltcalipsoice .or. cfg%Lcllcalipsoliq .or. cfg%Lclmcalipsoliq .or. & cfg%Lclhcalipsoliq .or. cfg%Lcltcalipsoliq .or. cfg%Lcllcalipsoun .or. & cfg%Lclmcalipsoun .or. cfg%Lclhcalipsoun .or. cfg%Lcltcalipsoun) then stlidar%cldlayerphase = cospOUT%calipso_cldlayerphase endif if (cfg%Lclcalipsotmp .or. cfg%Lclcalipsotmpliq .or. cfg%Lclcalipsoice .or. cfg%Lclcalipsotmpun) then stlidar%lidarcldtmp = cospOUT%calipso_lidarcldtmp endif ! Fields present, but not controlled by logical switch if (any([cfg%Lclcalipsoliq,cfg%Lclcalipsoice,cfg%Lclcalipsoun,cfg%Lclcalipsotmp, & cfg%Lclcalipsotmpliq,cfg%Lclcalipsotmpice,cfg%Lclcalipsotmpun,cfg%Lclhcalipsoliq,& cfg%Lcllcalipsoliq,cfg%Lclmcalipsoliq,cfg%Lcltcalipsoliq,cfg%Lclhcalipsoice,& cfg%Lcllcalipsoice,cfg%Lclmcalipsoice,cfg%Lcltcalipsoice,cfg%Lclhcalipsoun,& cfg%Lcllcalipsoun,cfg%Lclmcalipsoun,cfg%Lcltcalipsoun])) then sglidar%temp_tot = cospOUT%calipso_temp_tot(:,sglidar%Nlevels:1:-1) sglidar%tau_tot = cospOUT%calipso_tau_tot(:,:,sglidar%Nlevels:1:-1) endif endif ! Cloudsat if (cfg%Lradar_sim) then ! *NOTE* In COSP2 all outputs are ordered from TOA-2-SFC, but in COSPv1.4 this is ! not true. To maintain the outputs of v1.4, the affected fields are flipped. if (cfg%Ldbze94) then sgradar%Ze_tot = cospOUT%cloudsat_Ze_tot!(:,:,sgradar%Nlevels:1:-1) endif if (cfg%LcfadDbze94) then stradar%cfad_ze = cospOUT%cloudsat_cfad_ze(:,:,stradar%Nlevels:1:-1) endif endif ! Combined instrument products if (cfg%Lclcalipso2) then stradar%lidar_only_freq_cloud = cospOUT%lidar_only_freq_cloud(:,stradar%Nlevels:1:-1) endif if (cfg%Lcltlidarradar) stradar%radar_lidar_tcc = cospOUT%radar_lidar_tcc ! Subcolumns sgx%frac_out = sgx%frac_out(:,:,sgx%Nlevels:1:-1) ! Clean-up memory call destroy_cosp_outputs(cospOUT) deallocate(vgrid_zl,vgrid_zu,vgrid_z) end subroutine cosp_interface_v1p4 !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE subsample_and_optics !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine subsample_and_optics(overlap,gbx,sgx,cfg,npoints,start_idx,end_idx,cospIN,cospgridIN) ! Inputs integer, intent(in) :: overlap ! Overlap type in SCOPS: 1=max, 2=rand, 3=max/rand type(cosp_gridbox),intent(in) :: gbx ! Grid box description type(cosp_config),intent(in) :: cfg ! Configuration information type(cosp_subgrid),intent(inout) :: sgx ! Sub-grid scale description integer,intent(in) :: & npoints, & ! Number of points start_idx, & ! Starting index for subsetting input data. end_idx ! Ending index for subsetting input data. ! Outputs type(cosp_optical_inputs),intent(inout) :: & cospIN ! Optical (or derived) fields needed by simulators type(cosp_column_inputs),intent(inout) :: & cospgridIN ! Model fields needed by simulators ! Local variables integer :: i,j,k,ij real(wp),dimension(npoints,gbx%Nlevels) :: column_frac_out,column_prec_out real(wp),dimension(:,:), allocatable :: frac_ls,frac_cv,prec_ls,prec_cv,ls_p_rate,& cv_p_rate,g_vol real(wp),dimension(:,:,:),allocatable :: hm_matrix,re_matrix, & Np_matrix,MODIS_cloudWater,MODIS_cloudIce, & MODIS_watersize,MODIS_iceSize, & MODIS_opticalThicknessLiq, & MODIS_opticalThicknessIce real(wp),dimension(:,:,:,:),allocatable :: mr_hydro,Reff,Np type(rng_state),allocatable,dimension(:) :: rngs ! Seeds for random number generator integer,dimension(:),allocatable :: seed logical :: cmpGases=.true. !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Initialize COSP inputs !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% cospIN%tautot_S_liq = 0._wp cospIN%tautot_S_ice = 0._wp cospIN%emsfc_lw = gbx%isccp_emsfc_lw cospIN%rcfg_cloudsat = rcfg_cloudsat cospgridIN%hgt_matrix(1:nPoints,1:gbx%Nlevels) = gbx%zlev(start_idx:end_idx,gbx%Nlevels:1:-1) cospgridIN%hgt_matrix_half(1:nPoints,1:gbx%Nlevels) = gbx%zlev_half(start_idx:end_idx,gbx%Nlevels:1:-1) cospgridIN%sunlit(1:nPoints) = gbx%sunlit(start_idx:end_idx) cospgridIN%skt(1:nPoints) = gbx%skt(start_idx:end_idx) cospgridIN%land(1:nPoints) = gbx%land(start_idx:end_idx) cospgridIN%qv(1:nPoints,1:gbx%Nlevels) = gbx%sh(start_idx:end_idx,gbx%Nlevels:1:-1) cospgridIN%at(1:nPoints,1:gbx%Nlevels) = gbx%T(start_idx:end_idx,gbx%Nlevels:1:-1) cospgridIN%pfull(1:nPoints,1:gbx%Nlevels) = gbx%p(start_idx:end_idx,gbx%Nlevels:1:-1) cospgridIN%o3(1:nPoints,1:gbx%Nlevels) = gbx%mr_ozone(start_idx:end_idx,gbx%Nlevels:1:-1)*(amd/amO3)*1e6 cospgridIN%u_sfc(1:nPoints) = gbx%u_wind(start_idx:end_idx) cospgridIN%v_sfc(1:nPoints) = gbx%v_wind(start_idx:end_idx) cospgridIN%emis_sfc = gbx%surfem cospgridIN%lat(1:nPoints) = gbx%latitude(start_idx:end_idx) cospgridIN%lon(1:nPoints) = gbx%longitude(start_idx:end_idx) cospgridIN%month = 2 ! This is needed by RTTOV only for the surface emissivity calculation. cospgridIN%co2 = gbx%co2*(amd/amCO2)*1e6 cospgridIN%ch4 = gbx%ch4*(amd/amCH4)*1e6 cospgridIN%n2o = gbx%n2o*(amd/amN2O)*1e6 cospgridIN%co = gbx%co*(amd/amCO)*1e6 cospgridIN%zenang = gbx%zenang cospgridIN%phalf(:,1) = 0._wp cospgridIN%phalf(:,2:gbx%Nlevels+1) = gbx%ph(start_idx:end_idx,gbx%Nlevels:1:-1) if (gbx%Ncolumns .gt. 1) then !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Random number generator !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% allocate(rngs(Npoints),seed(Npoints)) seed(:)=0 seed = int(gbx%psfc) ! In case of Npoints=1 if (Npoints .gt. 1) seed=int((gbx%psfc(start_idx:end_idx)-minval(gbx%psfc(start_idx:end_idx)))/ & (maxval(gbx%psfc(start_idx:end_idx))-minval(gbx%psfc(start_idx:end_idx)))*100000) + 1 call init_rng(rngs, seed) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Generate subcolumns for clouds (SCOPS) and precipitation type (PREC_SCOPS) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Call SCOPS if (gbx%Ncolumns .gt. 1) then call scops(npoints,gbx%Nlevels,gbx%Ncolumns,rngs, & gbx%tca(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%cca(start_idx:end_idx,gbx%Nlevels:1:-1),overlap, & sgx%frac_out(start_idx:end_idx,:,:),0) deallocate(seed,rngs) else sgx%frac_out(start_idx:end_idx,:,:) = 1 endif cospIN%frac_out=sgx%frac_out(start_idx:end_idx,:,:) ! Sum up precipitation rates allocate(ls_p_rate(npoints,gbx%Nlevels),cv_p_rate(npoints,gbx%Nlevels)) if(gbx%use_precipitation_fluxes) then ls_p_rate(:,gbx%Nlevels:1:-1) = gbx%rain_ls(start_idx:end_idx,1:gbx%Nlevels) + & gbx%snow_ls(start_idx:end_idx,1:gbx%Nlevels) + & gbx%grpl_ls(start_idx:end_idx,1:gbx%Nlevels) cv_p_rate(:,gbx%Nlevels:1:-1) = gbx%rain_cv(start_idx:end_idx,1:gbx%Nlevels) + & gbx%snow_cv(start_idx:end_idx,1:gbx%Nlevels) else ls_p_rate(:,gbx%Nlevels:1:-1) = & gbx%mr_hydro(start_idx:end_idx,1:gbx%Nlevels,I_LSRAIN) + & gbx%mr_hydro(start_idx:end_idx,1:gbx%Nlevels,I_LSSNOW) + & gbx%mr_hydro(start_idx:end_idx,1:gbx%Nlevels,I_LSGRPL) cv_p_rate(:,gbx%Nlevels:1:-1) = & gbx%mr_hydro(start_idx:end_idx,1:gbx%Nlevels,I_CVRAIN) + & gbx%mr_hydro(start_idx:end_idx,1:gbx%Nlevels,I_CVSNOW) endif ! Call PREC_SCOPS call prec_scops(npoints,gbx%Nlevels,gbx%Ncolumns,ls_p_rate,cv_p_rate, & sgx%frac_out(start_idx:end_idx,:,:), & sgx%prec_frac(start_idx:end_idx,:,:)) deallocate(ls_p_rate,cv_p_rate) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Compute precipitation fraction in each gridbox !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Allocate allocate(frac_ls(npoints,gbx%Nlevels),prec_ls(npoints,gbx%Nlevels), & frac_cv(npoints,gbx%Nlevels),prec_cv(npoints,gbx%Nlevels)) ! Initialize frac_ls(1:npoints,1:gbx%Nlevels) = 0._wp prec_ls(1:npoints,1:gbx%Nlevels) = 0._wp frac_cv(1:npoints,1:gbx%Nlevels) = 0._wp prec_cv(1:npoints,1:gbx%Nlevels) = 0._wp DO j=1,npoints,1 DO k=1,gbx%Nlevels,1 DO i=1,gbx%Ncolumns,1 if (sgx%frac_out(start_idx+j-1,i,gbx%Nlevels+1-k) == I_LSC) & frac_ls(j,k) = frac_ls(j,k)+1._wp if (sgx%frac_out(start_idx+j-1,i,gbx%Nlevels+1-k) == I_CVC) & frac_cv(j,k) = frac_cv(j,k)+1._wp if (sgx%prec_frac(start_idx+j-1,i,gbx%Nlevels+1-k) .eq. 1) & prec_ls(j,k) = prec_ls(j,k)+1._wp if (sgx%prec_frac(start_idx+j-1,i,gbx%Nlevels+1-k) .eq. 2) & prec_cv(j,k) = prec_cv(j,k)+1._wp if (sgx%prec_frac(start_idx+j-1,i,gbx%Nlevels+1-k) .eq. 3) & prec_cv(j,k) = prec_cv(j,k)+1._wp if (sgx%prec_frac(start_idx+j-1,i,gbx%Nlevels+1-k) .eq. 3) & prec_ls(j,k) = prec_ls(j,k)+1._wp enddo frac_ls(j,k)=frac_ls(j,k)/gbx%Ncolumns frac_cv(j,k)=frac_cv(j,k)/gbx%Ncolumns prec_ls(j,k)=prec_ls(j,k)/gbx%Ncolumns prec_cv(j,k)=prec_cv(j,k)/gbx%Ncolumns enddo enddo ! Flip SCOPS output from TOA-to-SFC to SFC-to-TOA sgx%frac_out(start_idx:end_idx,:,1:gbx%Nlevels) = & sgx%frac_out(start_idx:end_idx,:,gbx%Nlevels:1:-1) sgx%prec_frac(start_idx:end_idx,:,1:gbx%Nlevels) = & sgx%prec_frac(start_idx:end_idx,:,gbx%Nlevels:1:-1) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Compute mixing ratios, effective radii and precipitation fluxes for clouds ! and precipitation !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% allocate(mr_hydro(npoints, gbx%Ncolumns, gbx%Nlevels, gbx%Nhydro), & Reff( npoints, gbx%Ncolumns, gbx%Nlevels, gbx%Nhydro), & Np( npoints, gbx%Ncolumns, gbx%Nlevels, gbx%Nhydro)) mr_hydro(:,:,:,:) = 0._wp Reff(:,:,:,:) = 0._wp Np(:,:,:,:) = 0._wp DO k=1,gbx%Ncolumns ! Subcolumn cloud fraction column_frac_out = sgx%frac_out(start_idx:end_idx,k,:) ! LS clouds where (column_frac_out == I_LSC) mr_hydro(:,k,:,I_LSCLIQ) = gbx%mr_hydro(start_idx:end_idx,:,I_LSCLIQ) mr_hydro(:,k,:,I_LSCICE) = gbx%mr_hydro(start_idx:end_idx,:,I_LSCICE) Reff(:,k,:,I_LSCLIQ) = gbx%Reff(start_idx:end_idx,:,I_LSCLIQ) Reff(:,k,:,I_LSCICE) = gbx%Reff(start_idx:end_idx,:,I_LSCICE) Np(:,k,:,I_LSCLIQ) = gbx%Np(start_idx:end_idx,:,I_LSCLIQ) Np(:,k,:,I_LSCICE) = gbx%Np(start_idx:end_idx,:,I_LSCICE) ! CONV clouds elsewhere (column_frac_out == I_CVC) mr_hydro(:,k,:,I_CVCLIQ) = gbx%mr_hydro(start_idx:end_idx,:,I_CVCLIQ) mr_hydro(:,k,:,I_CVCICE) = gbx%mr_hydro(start_idx:end_idx,:,I_CVCICE) Reff(:,k,:,I_CVCLIQ) = gbx%Reff(start_idx:end_idx,:,I_CVCLIQ) Reff(:,k,:,I_CVCICE) = gbx%Reff(start_idx:end_idx,:,I_CVCICE) Np(:,k,:,I_CVCLIQ) = gbx%Np(start_idx:end_idx,:,I_CVCLIQ) Np(:,k,:,I_CVCICE) = gbx%Np(start_idx:end_idx,:,I_CVCICE) end where ! Subcolumn precipitation column_prec_out = sgx%prec_frac(start_idx:end_idx,k,:) ! LS Precipitation where ((column_prec_out == 1) .or. (column_prec_out == 3) ) Reff(:,k,:,I_LSRAIN) = gbx%Reff(start_idx:end_idx,:,I_LSRAIN) Reff(:,k,:,I_LSSNOW) = gbx%Reff(start_idx:end_idx,:,I_LSSNOW) Reff(:,k,:,I_LSGRPL) = gbx%Reff(start_idx:end_idx,:,I_LSGRPL) Np(:,k,:,I_LSRAIN) = gbx%Np(start_idx:end_idx,:,I_LSRAIN) Np(:,k,:,I_LSSNOW) = gbx%Np(start_idx:end_idx,:,I_LSSNOW) Np(:,k,:,I_LSGRPL) = gbx%Np(start_idx:end_idx,:,I_LSGRPL) ! CONV precipitation elsewhere ((column_prec_out == 2) .or. (column_prec_out == 3)) Reff(:,k,:,I_CVRAIN) = gbx%Reff(start_idx:end_idx,:,I_CVRAIN) Reff(:,k,:,I_CVSNOW) = gbx%Reff(start_idx:end_idx,:,I_CVSNOW) Np(:,k,:,I_CVRAIN) = gbx%Np(start_idx:end_idx,:,I_CVRAIN) Np(:,k,:,I_CVSNOW) = gbx%Np(start_idx:end_idx,:,I_CVSNOW) end where enddo !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Convert the mixing ratio and precipitation fluxes from gridbox mean to ! the fraction-based values !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% DO k=1,gbx%Nlevels DO j=1,npoints ! Clouds if (frac_ls(j,k) .ne. 0.) then mr_hydro(j,:,k,I_LSCLIQ) = mr_hydro(j,:,k,I_LSCLIQ)/frac_ls(j,k) mr_hydro(j,:,k,I_LSCICE) = mr_hydro(j,:,k,I_LSCICE)/frac_ls(j,k) endif if (frac_cv(j,k) .ne. 0.) then mr_hydro(j,:,k,I_CVCLIQ) = mr_hydro(j,:,k,I_CVCLIQ)/frac_cv(j,k) mr_hydro(j,:,k,I_CVCICE) = mr_hydro(j,:,k,I_CVCICE)/frac_cv(j,k) endif ! Precipitation if (gbx%use_precipitation_fluxes) then if (prec_ls(j,k) .ne. 0.) then gbx%rain_ls(start_idx+j-1,k) = gbx%rain_ls(start_idx+j-1,k)/prec_ls(j,k) gbx%snow_ls(start_idx+j-1,k) = gbx%snow_ls(start_idx+j-1,k)/prec_ls(j,k) gbx%grpl_ls(start_idx+j-1,k) = gbx%grpl_ls(start_idx+j-1,k)/prec_ls(j,k) endif if (prec_cv(j,k) .ne. 0.) then gbx%rain_cv(start_idx+j-1,k) = gbx%rain_cv(start_idx+j-1,k)/prec_cv(j,k) gbx%snow_cv(start_idx+j-1,k) = gbx%snow_cv(start_idx+j-1,k)/prec_cv(j,k) endif else if (prec_ls(j,k) .ne. 0.) then mr_hydro(j,:,k,I_LSRAIN) = mr_hydro(j,:,k,I_LSRAIN)/prec_ls(j,k) mr_hydro(j,:,k,I_LSSNOW) = mr_hydro(j,:,k,I_LSSNOW)/prec_ls(j,k) mr_hydro(j,:,k,I_LSGRPL) = mr_hydro(j,:,k,I_LSGRPL)/prec_ls(j,k) endif if (prec_cv(j,k) .ne. 0.) then mr_hydro(j,:,k,I_CVRAIN) = mr_hydro(j,:,k,I_CVRAIN)/prec_cv(j,k) mr_hydro(j,:,k,I_CVSNOW) = mr_hydro(j,:,k,I_CVSNOW)/prec_cv(j,k) endif endif enddo enddo deallocate(frac_ls,prec_ls,frac_cv,prec_cv) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! Convert precipitation fluxes to mixing ratios !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (gbx%use_precipitation_fluxes) then call cosp_precip_mxratio(npoints, gbx%Nlevels, gbx%Ncolumns, & gbx%p(start_idx:end_idx,:),gbx%T(start_idx:end_idx,:),& sgx%prec_frac(start_idx:end_idx,:,:), 1._wp, & n_ax(I_LSRAIN), n_bx(I_LSRAIN), alpha_x(I_LSRAIN), & c_x(I_LSRAIN), d_x(I_LSRAIN), g_x(I_LSRAIN), & a_x(I_LSRAIN), b_x(I_LSRAIN), gamma_1(I_LSRAIN), & gamma_2(I_LSRAIN),gamma_3(I_LSRAIN),gamma_4(I_LSRAIN),& gbx%rain_ls(start_idx:end_idx,:), & mr_hydro(:,:,:,I_LSRAIN),Reff(:,:,:,I_LSRAIN)) call cosp_precip_mxratio(npoints, gbx%Nlevels, gbx%Ncolumns, & gbx%p(start_idx:end_idx,:),gbx%T(start_idx:end_idx,:),& sgx%prec_frac(start_idx:end_idx,:,:), 1._wp, & n_ax(I_LSSNOW), n_bx(I_LSSNOW), alpha_x(I_LSSNOW), & c_x(I_LSSNOW), d_x(I_LSSNOW), g_x(I_LSSNOW), & a_x(I_LSSNOW), b_x(I_LSSNOW), gamma_1(I_LSSNOW), & gamma_2(I_LSSNOW),gamma_3(I_LSSNOW),gamma_4(I_LSSNOW),& gbx%snow_ls(start_idx:end_idx,:), & mr_hydro(:,:,:,I_LSSNOW),Reff(:,:,:,I_LSSNOW)) call cosp_precip_mxratio(npoints, gbx%Nlevels, gbx%Ncolumns, & gbx%p(start_idx:end_idx,:),gbx%T(start_idx:end_idx,:),& sgx%prec_frac(start_idx:end_idx,:,:), 2._wp, & n_ax(I_CVRAIN), n_bx(I_CVRAIN), alpha_x(I_CVRAIN), & c_x(I_CVRAIN), d_x(I_CVRAIN), g_x(I_CVRAIN), & a_x(I_CVRAIN), b_x(I_CVRAIN), gamma_1(I_CVRAIN), & gamma_2(I_CVRAIN),gamma_3(I_CVRAIN),gamma_4(I_CVRAIN),& gbx%rain_cv(start_idx:end_idx,:), & mr_hydro(:,:,:,I_CVRAIN),Reff(:,:,:,I_CVRAIN)) call cosp_precip_mxratio(npoints, gbx%Nlevels, gbx%Ncolumns, & gbx%p(start_idx:end_idx,:),gbx%T(start_idx:end_idx,:),& sgx%prec_frac(start_idx:end_idx,:,:), 2._wp, & n_ax(I_CVSNOW), n_bx(I_CVSNOW), alpha_x(I_CVSNOW), & c_x(I_CVSNOW), d_x(I_CVSNOW), g_x(I_CVSNOW), & a_x(I_CVSNOW), b_x(I_CVSNOW), gamma_1(I_CVSNOW), & gamma_2(I_CVSNOW),gamma_3(I_CVSNOW),gamma_4(I_CVSNOW),& gbx%snow_cv(start_idx:end_idx,:), & mr_hydro(:,:,:,I_CVSNOW),Reff(:,:,:,I_CVSNOW)) call cosp_precip_mxratio(npoints, gbx%Nlevels, gbx%Ncolumns, & gbx%p(start_idx:end_idx,:),gbx%T(start_idx:end_idx,:),& sgx%prec_frac(start_idx:end_idx,:,:), 1._wp, & n_ax(I_LSGRPL), n_bx(I_LSGRPL), alpha_x(I_LSGRPL), & c_x(I_LSGRPL), d_x(I_LSGRPL), g_x(I_LSGRPL), & a_x(I_LSGRPL), b_x(I_LSGRPL), gamma_1(I_LSGRPL), & gamma_2(I_LSGRPL),gamma_3(I_LSGRPL),gamma_4(I_LSGRPL),& gbx%grpl_ls(start_idx:end_idx,:), & mr_hydro(:,:,:,I_LSGRPL),Reff(:,:,:,I_LSGRPL)) endif else allocate(mr_hydro(npoints, 1, gbx%Nlevels, gbx%Nhydro), & Reff(npoints, 1, gbx%Nlevels, gbx%Nhydro), & Np(npoints, 1, gbx%Nlevels, gbx%Nhydro)) mr_hydro(:,1,:,:) = gbx%mr_hydro(start_idx:end_idx,:,:) Reff(:,1,:,:) = gbx%Reff(start_idx:end_idx,:,:) Np(:,1,:,:) = gbx%Np(start_idx:end_idx,:,:) where(gbx%dtau_s(start_idx:end_idx,:) .gt. 0) sgx%frac_out(start_idx:end_idx,1,:) = 1 endwhere endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 11 micron emissivity !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% call cosp_simulator_optics(npoints,gbx%Ncolumns,gbx%Nlevels, & sgx%frac_out(start_idx:end_idx,:,gbx%Nlevels:1:-1), & gbx%dem_c(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%dem_s(start_idx:end_idx,gbx%Nlevels:1:-1), & cospIN%emiss_11) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! 0.67 micron optical depth !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% call cosp_simulator_optics(npoints,gbx%Ncolumns,gbx%Nlevels, & sgx%frac_out(start_idx:end_idx,:,gbx%Nlevels:1:-1), & gbx%dtau_c(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%dtau_s(start_idx:end_idx,gbx%Nlevels:1:-1), & cospIN%tau_067) !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! LIDAR Polarized optics !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (cfg%Llidar_sim) then call lidar_optics(npoints,gbx%Ncolumns,gbx%Nlevels,4,gbx%lidar_ice_type, & mr_hydro(:,:,cospIN%Nlevels:1:-1,I_LSCLIQ), & mr_hydro(:,:,cospIN%Nlevels:1:-1,I_LSCICE), & mr_hydro(:,:,cospIN%Nlevels:1:-1,I_CVCLIQ), & mr_hydro(:,:,cospIN%Nlevels:1:-1,I_CVCICE), & gbx%Reff(start_idx:end_idx,cospIN%Nlevels:1:-1,I_LSCLIQ), & gbx%Reff(start_idx:end_idx,cospIN%Nlevels:1:-1,I_LSCICE), & gbx%Reff(start_idx:end_idx,cospIN%Nlevels:1:-1,I_CVCLIQ), & gbx%Reff(start_idx:end_idx,cospIN%Nlevels:1:-1,I_CVCICE), & cospgridIN%pfull,cospgridIN%phalf,cospgridIN%at, & cospIN%beta_mol,cospIN%betatot,cospIN%tau_mol,cospIN%tautot, & cospIN%tautot_S_liq,cospIN%tautot_S_ice, & betatot_ice = cospIN%betatot_ice, & betatot_liq=cospIN%betatot_liq,tautot_ice=cospIN%tautot_ice, & tautot_liq = cospIN%tautot_liq) endif !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! CLOUDSAT RADAR OPTICS !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (cfg%Lradar_sim) then allocate(g_vol(nPoints,gbx%Nlevels)) DO ij=1,gbx%Ncolumns if (ij .eq. 1) then cmpGases = .true. call quickbeam_optics(sd, rcfg_cloudsat,npoints,gbx%Nlevels, R_UNDEF, & mr_hydro(:,ij,gbx%Nlevels:1:-1,1:N_HYDRO)*1000._wp, & Reff(:,ij,gbx%Nlevels:1:-1,1:N_HYDRO)*1.e6_wp, & Np(:,ij,gbx%Nlevels:1:-1,1:N_HYDRO), & gbx%p(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%T(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%sh(start_idx:end_idx,gbx%Nlevels:1:-1),cmpGases, & cospIN%z_vol_cloudsat(1:npoints,ij,:), & cospIN%kr_vol_cloudsat(1:npoints,ij,:), & cospIN%g_vol_cloudsat(1:npoints,ij,:),g_vol_out=g_vol) else cmpGases = .false. call quickbeam_optics(sd, rcfg_cloudsat,npoints,gbx%Nlevels, R_UNDEF, & mr_hydro(:,ij,gbx%Nlevels:1:-1,1:N_HYDRO)*1000._wp, & Reff(:,ij,gbx%Nlevels:1:-1,1:N_HYDRO)*1.e6_wp, & Np(:,ij,gbx%Nlevels:1:-1,1:N_HYDRO), & gbx%p(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%T(start_idx:end_idx,gbx%Nlevels:1:-1), & gbx%sh(start_idx:end_idx,gbx%Nlevels:1:-1),cmpGases, & cospIN%z_vol_cloudsat(1:npoints,ij,:), & cospIN%kr_vol_cloudsat(1:npoints,ij,:), & cospIN%g_vol_cloudsat(1:npoints,ij,:),g_vol_in=g_vol) end if enddo end if !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! MODIS optics !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% if (cfg%Lmodis_sim) then ! Allocate memory allocate(MODIS_cloudWater(npoints,gbx%Ncolumns,gbx%Nlevels), & MODIS_cloudIce(npoints,gbx%Ncolumns,gbx%Nlevels), & MODIS_waterSize(npoints,gbx%Ncolumns,gbx%Nlevels), & MODIS_iceSize(npoints,gbx%Ncolumns,gbx%Nlevels), & MODIS_opticalThicknessLiq(npoints,gbx%Ncolumns,gbx%Nlevels), & MODIS_opticalThicknessIce(npoints,gbx%Ncolumns,gbx%Nlevels)) ! Cloud water call cosp_simulator_optics(npoints,gbx%Ncolumns,gbx%Nlevels, & sgx%frac_out(start_idx:end_idx,:,:),mr_hydro(:,:,:,I_CVCLIQ), & mr_hydro(:,:,:,I_LSCLIQ),MODIS_cloudWater(:, :, gbx%Nlevels:1:-1)) ! Cloud ice call cosp_simulator_optics(npoints,gbx%Ncolumns,gbx%Nlevels, & sgx%frac_out(start_idx:end_idx,:,:),mr_hydro(:,:,:,I_CVCICE), & mr_hydro(:,:,:,I_LSCICE),MODIS_cloudIce(:, :, gbx%Nlevels:1:-1)) ! Water droplet size call cosp_simulator_optics(npoints,gbx%Ncolumns,gbx%Nlevels, & sgx%frac_out(start_idx:end_idx,:,:),reff(:,:,:,I_CVCLIQ), & reff(:,:,:,I_LSCLIQ),MODIS_waterSize(:, :, gbx%Nlevels:1:-1)) ! Ice crystal size call cosp_simulator_optics(npoints,gbx%Ncolumns,gbx%Nlevels, & sgx%frac_out(start_idx:end_idx,:,:),reff(:,:,:,I_CVCICE), & reff(:,:,:,I_LSCICE),MODIS_iceSize(:, :, gbx%Nlevels:1:-1)) ! Partition optical thickness into liquid and ice parts call modis_optics_partition(npoints,gbx%Nlevels,gbx%Ncolumns,MODIS_cloudWater, & MODIS_cloudIce,MODIS_waterSize,MODIS_iceSize,cospIN%tau_067, & MODIS_opticalThicknessLiq, MODIS_opticalThicknessIce) ! Compute assymetry parameter and single scattering albedo call modis_optics(npoints,gbx%Nlevels,gbx%Ncolumns,MODIS_opticalThicknessLiq, & MODIS_waterSize*1.0e6_wp,MODIS_opticalThicknessIce,MODIS_iceSize*1.0e6_wp, & cospIN%fracLiq, cospIN%asym, cospIN%ss_alb) ! Deallocate memory deallocate(MODIS_cloudWater,MODIS_cloudIce,MODIS_WaterSize,MODIS_iceSize, & MODIS_opticalThicknessLiq,MODIS_opticalThicknessIce,mr_hydro, & Reff,Np) end if end subroutine subsample_and_optics !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_gridbox !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_cosp_gridbox(time,time_bnds,radar_freq,surface_radar, & use_mie_tables,use_gas_abs,do_ray,melt_lay,k2, & Npoints,Nlevels,Ncolumns,Nhydro,Nprmts_max_hydro,& Naero,Nprmts_max_aero,Npoints_it,lidar_ice_type, & isccp_top_height,isccp_top_height_direction, & isccp_overlap,isccp_emsfc_lw, & use_precipitation_fluxes,use_reff,Plat,Sat,Inst, & Nchan,ZenAng,Ichan,SurfEm,co2,ch4,n2o,co, & y,load_LUT) ! Inputs double precision,intent(in) :: & time, & ! Time since start of run [days] time_bnds(2) ! Time boundaries integer,intent(in) :: & surface_radar, & ! surface=1,spaceborne=0 use_mie_tables, & ! use a precomputed lookup table? yes=1,no=0,2=use first ! column everywhere use_gas_abs, & ! include gaseous absorption? yes=1,no=0 do_ray, & ! calculate/output Rayleigh refl=1, not=0 melt_lay, & ! melting layer model off=0, on=1 Npoints, & ! Number of gridpoints Nlevels, & ! Number of levels Ncolumns, & ! Number of columns Nhydro, & ! Number of hydrometeors Nprmts_max_hydro, & ! Max number of parameters for hydrometeor size ! distributions Naero, & ! Number of aerosol species Nprmts_max_aero, & ! Max number of parameters for aerosol size distributions Npoints_it, & ! Number of gridpoints processed in one iteration lidar_ice_type, & ! Ice particle shape in lidar calculations (0=ice-spheres ; ! 1=ice-non-spherical) isccp_top_height , & ! isccp_top_height_direction, & ! isccp_overlap, & ! Plat, & ! RTTOV satellite platform Sat, & ! RTTOV satellite Inst, & ! RTTOV instrument Nchan ! RTTOV number of channels integer,intent(in),dimension(Nchan) :: & Ichan real(wp),intent(in) :: & radar_freq, & ! Radar frequency [GHz] k2, & ! |K|^2, -1=use frequency dependent default isccp_emsfc_lw, & ! 11microm surface emissivity co2, & ! CO2 ch4, & ! CH4 n2o, & ! N2O co, & ! CO ZenAng ! RTTOV zenith abgle real(wp),intent(in),dimension(Nchan) :: & SurfEm logical,intent(in) :: & use_precipitation_fluxes,& use_reff logical,intent(in),optional :: load_LUT ! Outputs type(cosp_gridbox),intent(out) :: y ! local variables logical :: local_load_LUT if (present(load_LUT)) then local_load_LUT = load_LUT else local_load_LUT = RADAR_SIM_LOAD_scale_LUTs_flag endif ! Dimensions and scalars y%radar_freq = radar_freq y%surface_radar = surface_radar y%use_mie_tables = use_mie_tables y%use_gas_abs = use_gas_abs y%do_ray = do_ray y%melt_lay = melt_lay y%k2 = k2 y%Npoints = Npoints y%Nlevels = Nlevels y%Ncolumns = Ncolumns y%Nhydro = Nhydro y%Nprmts_max_hydro = Nprmts_max_hydro y%Naero = Naero y%Nprmts_max_aero = Nprmts_max_aero y%Npoints_it = Npoints_it y%lidar_ice_type = lidar_ice_type y%isccp_top_height = isccp_top_height y%isccp_top_height_direction = isccp_top_height_direction y%isccp_overlap = isccp_overlap y%isccp_emsfc_lw = isccp_emsfc_lw y%use_precipitation_fluxes = use_precipitation_fluxes y%use_reff = use_reff y%time = time y%time_bnds = time_bnds ! RTTOV parameters y%Plat = Plat y%Sat = Sat y%Inst = Inst y%Nchan = Nchan y%ZenAng = ZenAng y%co2 = co2 y%ch4 = ch4 y%n2o = n2o y%co = co ! Gridbox information (Npoints,Nlevels) allocate(y%zlev(Npoints,Nlevels),y%zlev_half(Npoints,Nlevels), & y%dlev(Npoints,Nlevels),y%p(Npoints,Nlevels),y%ph(Npoints,Nlevels), & y%T(Npoints,Nlevels),y%q(Npoints,Nlevels), y%sh(Npoints,Nlevels), & y%dtau_s(Npoints,Nlevels),y%dtau_c(Npoints,Nlevels), & y%dem_s(Npoints,Nlevels),y%dem_c(Npoints,Nlevels),y%tca(Npoints,Nlevels), & y%cca(Npoints,Nlevels),y%rain_ls(Npoints,Nlevels), & y%rain_cv(Npoints,Nlevels),y%grpl_ls(Npoints,Nlevels), & y%snow_ls(Npoints,Nlevels),y%snow_cv(Npoints,Nlevels), & y%mr_ozone(Npoints,Nlevels)) ! Surface information and geolocation (Npoints) allocate(y%toffset(Npoints),y%longitude(Npoints),y%latitude(Npoints),y%psfc(Npoints),& y%land(Npoints),y%sunlit(Npoints),y%skt(Npoints),y%u_wind(Npoints), & y%v_wind(Npoints)) ! Hydrometeors concentration and distribution parameters allocate(y%mr_hydro(Npoints,Nlevels,Nhydro),y%Reff(Npoints,Nlevels,Nhydro), & y%dist_prmts_hydro(Nprmts_max_hydro,Nhydro),y%Np(Npoints,Nlevels,Nhydro)) ! Aerosols concentration and distribution parameters allocate(y%conc_aero(Npoints,Nlevels,Naero), y%dist_type_aero(Naero), & y%dist_prmts_aero(Npoints,Nlevels,Nprmts_max_aero,Naero)) ! RTTOV channels and sfc. emissivity allocate(y%ichan(Nchan),y%surfem(Nchan)) y%ichan = ichan y%surfem = surfem ! Initialize y%zlev = 0.0 y%zlev_half = 0.0 y%dlev = 0.0 y%p = 0.0 y%ph = 0.0 y%T = 0.0 y%q = 0.0 y%sh = 0.0 y%dtau_s = 0.0 y%dtau_c = 0.0 y%dem_s = 0.0 y%dem_c = 0.0 y%tca = 0.0 y%cca = 0.0 y%rain_ls = 0.0 y%rain_cv = 0.0 y%grpl_ls = 0.0 y%snow_ls = 0.0 y%snow_cv = 0.0 y%Reff = 0.0 y%Np = 0.0 y%mr_ozone = 0.0 y%u_wind = 0.0 y%v_wind = 0.0 y%toffset = 0.0 y%longitude = 0.0 y%latitude = 0.0 y%psfc = 0.0 y%land = 0.0 y%sunlit = 0.0 y%skt = 0.0 y%mr_hydro = 0.0 y%dist_prmts_hydro = 0.0 y%conc_aero = 0.0 y%dist_type_aero = 0 y%dist_prmts_aero = 0.0 END SUBROUTINE CONSTRUCT_cosp_gridbox !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_gridbox !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE destroy_cosp_gridbox(y,save_LUT) type(cosp_gridbox),intent(inout) :: y logical,intent(in),optional :: save_LUT logical :: local_save_LUT if (present(save_LUT)) then local_save_LUT = save_LUT else local_save_LUT = RADAR_SIM_UPDATE_scale_LUTs_flag endif ! save any updates to radar simulator LUT if (local_save_LUT) call save_scale_LUTs(y%hp) deallocate(y%zlev,y%zlev_half,y%dlev,y%p,y%ph,y%T,y%q,y%sh,y%dtau_s,y%dtau_c,y%dem_s,& y%dem_c,y%toffset,y%longitude,y%latitude,y%psfc,y%land,y%tca,y%cca, & y%mr_hydro,y%dist_prmts_hydro,y%conc_aero,y%dist_type_aero, & y%dist_prmts_aero,y%rain_ls,y%rain_cv,y%snow_ls,y%snow_cv,y%grpl_ls, & y%sunlit,y%skt,y%Reff,y%Np,y%ichan,y%surfem,y%mr_ozone,y%u_wind,y%v_wind) END SUBROUTINE destroy_cosp_gridbox !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_subgrid !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_COSP_SUBGRID(Npoints,Ncolumns,Nlevels,y) ! Inputs integer,intent(in) :: & Npoints, & ! Number of gridpoints Ncolumns, & ! Number of columns Nlevels ! Number of levels ! Outputs type(cosp_subgrid),intent(out) :: y ! Dimensions y%Npoints = Npoints y%Ncolumns = Ncolumns y%Nlevels = Nlevels ! Allocate allocate(y%frac_out(Npoints,Ncolumns,Nlevels)) if (Ncolumns > 1) then allocate(y%prec_frac(Npoints,Ncolumns,Nlevels)) else ! CRM mode, not needed allocate(y%prec_frac(1,1,1)) endif ! Initialize y%prec_frac = 0._wp y%frac_out = 0._wp END SUBROUTINE CONSTRUCT_COSP_SUBGRID ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE save_scale_LUTs ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine save_scale_LUTs(hp) type(class_param), intent(inout) :: hp logical :: LUT_file_exists integer :: i,j,k,ind inquire(file=trim(hp%scale_LUT_file_name) // '_radar_Z_scale_LUT.dat', & exist=LUT_file_exists) OPEN(unit=12,file=trim(hp%scale_LUT_file_name) // '_radar_Z_scale_LUT.dat',& form='unformatted',err= 99,access='DIRECT',recl=28) write(*,*) 'Creating or Updating radar LUT file: ', & trim(hp%scale_LUT_file_name) // '_radar_Z_scale_LUT.dat' DO i=1,maxhclass DO j=1,mt_ntt DO k=1,nRe_types ind = i+(j-1)*maxhclass+(k-1)*(nRe_types*mt_ntt) if(.not.LUT_file_exists .or. hp%Z_scale_added_flag(i,j,k)) then hp%Z_scale_added_flag(i,j,k)=.false. write(12,rec=ind) hp%Z_scale_flag(i,j,k), & hp%Ze_scaled(i,j,k), & hp%Zr_scaled(i,j,k), & hp%kr_scaled(i,j,k) endif enddo enddo enddo close(unit=12) return 99 write(*,*) 'Error: Unable to create/update radar LUT file: ', & trim(hp%scale_LUT_file_name) // '_radar_Z_scale_LUT.dat' return end subroutine save_scale_LUTs !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% !SUBROUTINE construct_cosp_vgrid !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_COSP_VGRID(gbx,Nlvgrid,use_vgrid,cloudsat,x) type(cosp_gridbox),intent(in) :: gbx ! Gridbox information integer,intent(in) :: Nlvgrid ! Number of new levels logical,intent(in) :: use_vgrid! Logical flag that controls the output on a different grid logical,intent(in) :: cloudsat ! TRUE if a CloudSat like grid (480m) is requested type(cosp_vgrid),intent(out) :: x ! Local variables integer :: i REAL :: zstep x%use_vgrid = use_vgrid x%csat_vgrid = cloudsat ! Dimensions x%Npoints = gbx%Npoints x%Ncolumns = gbx%Ncolumns x%Nlevels = gbx%Nlevels ! --- Allocate arrays --- if (use_vgrid) then x%Nlvgrid = Nlvgrid else x%Nlvgrid = gbx%Nlevels endif allocate(x%z(x%Nlvgrid),x%zl(x%Nlvgrid),x%zu(x%Nlvgrid)) allocate(x%mz(x%Nlevels),x%mzl(x%Nlevels),x%mzu(x%Nlevels)) ! --- Model vertical levels --- ! Use height levels of first model gridbox x%mz = gbx%zlev(1,:) x%mzl = gbx%zlev_half(1,:) x%mzu(1:x%Nlevels-1) = gbx%zlev_half(1,2:x%Nlevels) x%mzu(x%Nlevels) = gbx%zlev(1,x%Nlevels) + (gbx%zlev(1,x%Nlevels) - x%mzl(x%Nlevels)) if (use_vgrid) then ! --- Initialise to zero --- x%z = 0.0 x%zl = 0.0 x%zu = 0.0 if (cloudsat) then ! --- CloudSat grid requested --- zstep = 480.0 else ! Other grid requested. Constant vertical spacing with top at 20 km zstep = 20000.0/x%Nlvgrid endif DO i=1,x%Nlvgrid x%zl(i) = (i-1)*zstep x%zu(i) = i*zstep enddo x%z = (x%zl + x%zu)/2.0 else x%z = x%mz x%zl = x%mzl x%zu = x%mzu endif END SUBROUTINE CONSTRUCT_COSP_VGRID !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_sgradar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine construct_cosp_sgradar(Npoints,Ncolumns,Nlevels,Nhydro,x) integer,target, intent(in) :: Npoints ! Number of sampled points integer,target, intent(in) :: Ncolumns ! Number of subgrid columns integer,target, intent(in) :: Nlevels ! Number of model levels integer,target, intent(in) :: Nhydro ! Number of hydrometeors type(cosp_sgradar), intent(out) :: x ! Dimensions x%Npoints => Npoints x%Ncolumns => Ncolumns x%Nlevels => Nlevels x%Nhydro => Nhydro ! Allocate allocate(x%att_gas(Npoints,Nlevels),x%Ze_tot(Npoints,Ncolumns,Nlevels)) ! Initialize x%att_gas = 0._wp x%Ze_tot = 0._wp end subroutine construct_cosp_sgradar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_radarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine construct_cosp_radarstats(Npoints,Ncolumns,Nlevels,Nhydro,x) integer,target, intent(in) :: Npoints ! Number of sampled points integer,target, intent(in) :: Ncolumns ! Number of subgrid columns integer,target, intent(in) :: Nlevels ! Number of model levels integer,target, intent(in) :: Nhydro ! Number of hydrometeors type(cosp_radarstats),intent(out) :: x ! Dimensions x%Npoints => Npoints x%Ncolumns => Ncolumns x%Nlevels => Nlevels x%Nhydro => Nhydro ! Allocate allocate(x%cfad_ze(Npoints,DBZE_BINS,Nlevels),x%lidar_only_freq_cloud(Npoints,Nlevels), & x%radar_lidar_tcc(Npoints)) ! Initialize x%cfad_ze = 0._wp x%lidar_only_freq_cloud = 0._wp x%radar_lidar_tcc = 0._wp end subroutine construct_cosp_radarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_subgrid !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_subgrid(y) type(cosp_subgrid),intent(inout) :: y deallocate(y%prec_frac, y%frac_out) end subroutine destroy_cosp_subgrid !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_sgradar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_sgradar(x) type(cosp_sgradar),intent(inout) :: x deallocate(x%att_gas,x%Ze_tot) end subroutine destroy_cosp_sgradar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_radarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_radarstats(x) type(cosp_radarstats),intent(inout) :: x deallocate(x%cfad_ze,x%lidar_only_freq_cloud,x%radar_lidar_tcc) end subroutine destroy_cosp_radarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_sglidar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine construct_cosp_sglidar(Npoints,Ncolumns,Nlevels,Nhydro,Nrefl,x) ! Inputs integer,intent(in),target :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nhydro, & ! Number of hydrometeors Nrefl ! Number of parasol reflectances ! parasol ! Outputs type(cosp_sglidar),intent(out) :: x ! Dimensions x%Npoints => Npoints x%Ncolumns => Ncolumns x%Nlevels => Nlevels x%Nhydro => Nhydro x%Nrefl => Nrefl ! Allocate allocate(x%beta_mol(x%Npoints,x%Nlevels), x%beta_tot(x%Npoints,x%Ncolumns,x%Nlevels), & x%tau_tot(x%Npoints,x%Ncolumns,x%Nlevels),x%refl(x%Npoints,x%Ncolumns,x%Nrefl), & x%temp_tot(x%Npoints,x%Nlevels),x%betaperp_tot(x%Npoints,x%Ncolumns,x%Nlevels)) ! Initialize x%beta_mol = 0._wp x%beta_tot = 0._wp x%tau_tot = 0._wp x%refl = 0._wp x%temp_tot = 0._wp x%betaperp_tot = 0._wp end subroutine construct_cosp_sglidar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_lidarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine construct_cosp_lidarstats(Npoints,Ncolumns,Nlevels,Nhydro,Nrefl,x) ! Inputs integer,intent(in),target :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nhydro, & ! Number of hydrometeors Nrefl ! Number of parasol reflectances ! Outputs type(cosp_lidarstats),intent(out) :: x ! Dimensions x%Npoints => Npoints x%Ncolumns => Ncolumns x%Nlevels => Nlevels x%Nhydro => Nhydro x%Nrefl => Nrefl ! Allocate allocate(x%srbval(SR_BINS),x%cfad_sr(x%Npoints,SR_BINS,x%Nlevels), & x%lidarcld(x%Npoints,x%Nlevels), x%cldlayer(x%Npoints,LIDAR_NCAT),& x%parasolrefl(x%Npoints,x%Nrefl),x%lidarcldphase(x%Npoints,x%Nlevels,6),& x%lidarcldtmp(x%Npoints,LIDAR_NTEMP,5),x%cldlayerphase(x%Npoints,LIDAR_NCAT,6)) ! Initialize x%srbval = 0._wp x%cfad_sr = 0._wp x%lidarcld = 0._wp x%cldlayer = 0._wp x%parasolrefl = 0._wp x%lidarcldphase = 0._wp x%cldlayerphase = 0._wp x%lidarcldtmp = 0._wp end subroutine construct_cosp_lidarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_lidarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_lidarstats(x) type(cosp_lidarstats),intent(inout) :: x deallocate(x%srbval,x%cfad_sr,x%lidarcld,x%cldlayer,x%parasolrefl,x%cldlayerphase, & x%lidarcldtmp,x%lidarcldphase) end subroutine destroy_cosp_lidarstats !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_sglidar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_sglidar(x) type(cosp_sglidar),intent(inout) :: x deallocate(x%beta_mol,x%beta_tot,x%tau_tot,x%refl,x%temp_tot,x%betaperp_tot) end subroutine destroy_cosp_sglidar !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_isccp !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_COSP_ISCCP(Npoints,Ncolumns,Nlevels,x) integer,target, intent(in) :: Npoints ! Number of sampled points integer,target, intent(in) :: Ncolumns ! Number of subgrid columns integer,target, intent(in) :: Nlevels ! Number of model levels type(cosp_isccp), intent(out) :: x ! Output x%Npoints => Npoints x%Ncolumns => Ncolumns x%Nlevels => Nlevels x%Npoints => Npoints x%Ncolumns => Ncolumns x%Nlevels => Nlevels ! Allocate allocate(x%fq_isccp(Npoints,7,7),x%totalcldarea(Npoints),x%meanptop(Npoints), & x%meantaucld(Npoints),x%meantb(Npoints),x%meantbclr(Npoints), & x%meanalbedocld(Npoints),x%boxtau(Npoints,Ncolumns), & x%boxptop(Npoints,Ncolumns)) ! Initialize x%fq_isccp = 0._wp x%totalcldarea = 0._wp x%meanptop = 0._wp x%meantaucld = 0._wp x%meantb = 0._wp x%meantbclr = 0._wp x%meanalbedocld= 0._wp x%boxtau = 0._wp x%boxptop = 0._wp END SUBROUTINE CONSTRUCT_COSP_ISCCP !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_isccp !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE destroy_cosp_isccp(x) type(cosp_isccp),intent(inout) :: x deallocate(x%fq_isccp,x%totalcldarea,x%meanptop,x%meantaucld,x%meantb,x%meantbclr, & x%meanalbedocld,x%boxtau,x%boxptop) END SUBROUTINE destroy_cosp_isccp ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_misr ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_COSP_MISR(Npoints,x) integer, intent(in),target :: Npoints ! Number of gridpoints type(cosp_misr), intent(out) :: x ! Local variables integer,target :: & Ntau=7,Ncth=numMISRHgtBins x%Npoints => Npoints x%Ntau => Ntau x%Nlevels => Ncth ! Allocate allocate(x%fq_MISR(x%Npoints,x%Ntau,x%Nlevels),x%MISR_meanztop(x%Npoints), & x%MISR_cldarea(x%Npoints),x%MISR_dist_model_layertops(x%Npoints,x%Nlevels)) ! Initialize x%fq_MISR = 0._wp x%MISR_meanztop = 0._wp x%MISR_cldarea = 0._wp x%MISR_dist_model_layertops = 0._wp END SUBROUTINE CONSTRUCT_COSP_MISR !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_misr !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE destroy_cosp_misr(x) type(cosp_misr),intent(inout) :: x if (associated(x%fq_MISR)) deallocate(x%fq_MISR) if (associated(x%MISR_meanztop)) deallocate(x%MISR_meanztop) if (associated(x%MISR_cldarea)) deallocate(x%MISR_cldarea) if (associated(x%MISR_dist_model_layertops)) deallocate(x%MISR_dist_model_layertops) END SUBROUTINE destroy_cosp_misr ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_modis ! %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_COSP_MODIS(nPoints, x) integer,target, intent(in) :: Npoints ! Number of sampled points type(cosp_MODIS), intent(out) :: x x%nPoints => nPoints ! Allocate gridmean variables allocate(x%Cloud_Fraction_Total_Mean(Npoints),x%Cloud_Fraction_Water_Mean(Npoints), & x%Cloud_Fraction_Ice_Mean(Npoints),x%Cloud_Fraction_High_Mean(Npoints), & x%Cloud_Fraction_Mid_Mean(Npoints),x%Cloud_Fraction_Low_Mean(Npoints), & x%Optical_Thickness_Total_Mean(Npoints), & x%Optical_Thickness_Water_Mean(Npoints), & x%Optical_Thickness_Ice_Mean(Npoints), & x%Optical_Thickness_Total_LogMean(Npoints), & x%Optical_Thickness_Water_LogMean(Npoints), & x%Optical_Thickness_Ice_LogMean(Npoints), & x%Cloud_Particle_Size_Water_Mean(Npoints), & x%Cloud_Particle_Size_Ice_Mean(Npoints), & x%Cloud_Top_Pressure_Total_Mean(Npoints),x%Liquid_Water_Path_Mean(Npoints), & x%Ice_Water_Path_Mean(Npoints), & x%Optical_Thickness_vs_Cloud_Top_Pressure(nPoints,ntauV1p4+1,numMODISPresBins),& x%Optical_Thickness_vs_ReffICE(nPoints,ntauV1p4+1,numMODISReffIceBins),& x%Optical_Thickness_vs_ReffLIQ(nPoints,ntauV1p4+1,numMODISReffLiqBins)) x%Optical_Thickness_vs_Cloud_Top_Pressure(:, :, :) = R_UNDEF x%Optical_Thickness_vs_ReffICE(:,:,:) = R_UNDEF x%Optical_Thickness_vs_ReffLIQ(:,:,:) = R_UNDEF END SUBROUTINE CONSTRUCT_COSP_MODIS !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_modis !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE destroy_cosp_modis(x) type(cosp_MODIS),intent(inout) :: x ! Free space used by cosp_modis variable. if(associated(x%Cloud_Fraction_Total_Mean)) deallocate(x%Cloud_Fraction_Total_Mean) if(associated(x%Cloud_Fraction_Water_Mean)) deallocate(x%Cloud_Fraction_Water_Mean) if(associated(x%Cloud_Fraction_Ice_Mean)) deallocate(x%Cloud_Fraction_Ice_Mean) if(associated(x%Cloud_Fraction_High_Mean)) deallocate(x%Cloud_Fraction_High_Mean) if(associated(x%Cloud_Fraction_Mid_Mean)) deallocate(x%Cloud_Fraction_Mid_Mean) if(associated(x%Cloud_Fraction_Low_Mean)) deallocate(x%Cloud_Fraction_Low_Mean) if(associated(x%Liquid_Water_Path_Mean)) deallocate(x%Liquid_Water_Path_Mean) if(associated(x%Ice_Water_Path_Mean)) deallocate(x%Ice_Water_Path_Mean) if(associated(x%Optical_Thickness_Total_Mean)) & deallocate(x%Optical_Thickness_Total_Mean) if(associated(x%Optical_Thickness_Water_Mean)) & deallocate(x%Optical_Thickness_Water_Mean) if(associated(x%Optical_Thickness_Ice_Mean)) & deallocate(x%Optical_Thickness_Ice_Mean) if(associated(x%Optical_Thickness_Total_LogMean)) & deallocate(x%Optical_Thickness_Total_LogMean) if(associated(x%Optical_Thickness_Water_LogMean)) & deallocate(x%Optical_Thickness_Water_LogMean) if(associated(x%Optical_Thickness_Ice_LogMean)) & deallocate(x%Optical_Thickness_Ice_LogMean) if(associated(x%Cloud_Particle_Size_Water_Mean)) & deallocate(x%Cloud_Particle_Size_Water_Mean) if(associated(x%Cloud_Particle_Size_Ice_Mean)) & deallocate(x%Cloud_Particle_Size_Ice_Mean) if(associated(x%Cloud_Top_Pressure_Total_Mean)) & deallocate(x%Cloud_Top_Pressure_Total_Mean) if(associated(x%Optical_Thickness_vs_Cloud_Top_Pressure)) & deallocate(x%Optical_Thickness_vs_Cloud_Top_Pressure) if(associated(x%Optical_Thickness_vs_ReffICE)) & deallocate(x%Optical_Thickness_vs_ReffICE) if(associated(x%Optical_Thickness_vs_ReffLIQ)) & deallocate(x%Optical_Thickness_vs_ReffLIQ) END SUBROUTINE destroy_cosp_modis !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cosp_rttov !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE CONSTRUCT_COSP_RTTOV(Npoints,Nchan,x) integer, intent(in) :: Npoints ! Number of sampled points integer, intent(in) :: Nchan ! Number of channels type(cosp_rttov), intent(out) :: x ! Allocate allocate(x%tbs(Npoints,Nchan)) ! Initialize x%tbs = 0.0 END SUBROUTINE CONSTRUCT_COSP_RTTOV !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_rttov !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% SUBROUTINE destroy_cosp_rttov(x) type(cosp_rttov),intent(inout) :: x ! Deallocate deallocate(x%tbs) END SUBROUTINE destroy_cosp_rttov !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_ !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_vgrid(x) type(cosp_vgrid),intent(inout) :: x deallocate(x%z, x%zl, x%zu, x%mz, x%mzl, x%mzu) end subroutine destroy_cosp_vgrid !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cospIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine construct_cospIN(npoints,ncolumns,nlevels,y) ! Inputs integer,intent(in) :: & npoints, & ! Number of horizontal gridpoints ncolumns, & ! Number of subcolumns nlevels ! Number of vertical levels ! Outputs type(cosp_optical_inputs),intent(out) :: y ! Dimensions y%Npoints = Npoints y%Ncolumns = Ncolumns y%Nlevels = Nlevels y%Npart = 4 y%Nrefl = PARASOL_NREFL allocate(y%tau_067(npoints, ncolumns,nlevels),& y%emiss_11(npoints, ncolumns,nlevels),& y%frac_out(npoints, ncolumns,nlevels),& y%betatot(npoints, ncolumns,nlevels),& y%betatot_ice(npoints, ncolumns,nlevels),& y%fracLiq(npoints, ncolumns,nlevels),& y%betatot_liq(npoints, ncolumns,nlevels),& y%tautot(npoints, ncolumns,nlevels),& y%tautot_ice(npoints, ncolumns,nlevels),& y%tautot_liq(npoints, ncolumns,nlevels),& y%z_vol_cloudsat(npoints, ncolumns,nlevels),& y%kr_vol_cloudsat(npoints,ncolumns,nlevels),& y%g_vol_cloudsat(npoints, ncolumns,nlevels),& y%asym(npoints, ncolumns,nlevels),& y%ss_alb(npoints, ncolumns,nlevels),& y%beta_mol(npoints, nlevels),& y%tau_mol(npoints, nlevels),& y%tautot_S_ice(npoints, ncolumns ),& y%tautot_S_liq(npoints, ncolumns)) end subroutine construct_cospIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE construct_cospstateIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine construct_cospstateIN(npoints,nlevels,nchan,y) ! Inputs integer,intent(in) :: & npoints, & ! Number of horizontal gridpoints nlevels, & ! Number of vertical levels nchan ! Number of channels ! Outputs type(cosp_column_inputs),intent(out) :: y allocate(y%sunlit(npoints),y%skt(npoints),y%land(npoints),y%at(npoints,nlevels), & y%pfull(npoints,nlevels),y%phalf(npoints,nlevels+1),y%qv(npoints,nlevels), & y%o3(npoints,nlevels),y%hgt_matrix(npoints,nlevels),y%u_sfc(npoints), & y%v_sfc(npoints),y%lat(npoints),y%lon(nPoints),y%emis_sfc(nchan), & y%cloudIce(nPoints,nLevels),y%cloudLiq(nPoints,nLevels), & y%fl_snow(nPoints,nLevels),y%fl_rain(nPoints,nLevels),y%seaice(npoints), & y%tca(nPoints,nLevels),y%hgt_matrix_half(npoints,nlevels+1)) end subroutine construct_cospstateIN ! ###################################################################################### ! SUBROUTINE construct_cosp_outputs ! This subroutine allocates output fields based on input logical flag switches. ! ###################################################################################### subroutine construct_cosp_outputs(Lpctisccp,Lclisccp,& Lboxptopisccp,Lboxtauisccp,Ltauisccp,Lcltisccp, & Lmeantbisccp,Lmeantbclrisccp,Lalbisccp,LclMISR, & Lcltmodis,Lclwmodis,Lclimodis,Lclhmodis,Lclmmodis, & Lcllmodis,Ltautmodis,Ltauwmodis,Ltauimodis, & Ltautlogmodis,Ltauwlogmodis,Ltauilogmodis, & Lreffclwmodis,Lreffclimodis,Lpctmodis,Llwpmodis, & Liwpmodis,Lclmodis,Latb532,LlidarBetaMol532, & LcfadLidarsr532,Lclcalipso2, & Lclcalipso,Lclhcalipso,Lcllcalipso,Lclmcalipso, & Lcltcalipso,Lcltlidarradar,Lclcalipsoliq, & Lclcalipsoice,Lclcalipsoun,Lclcalipsotmp, & Lclcalipsotmpliq,Lclcalipsotmpice,Lclcalipsotmpun, & Lcltcalipsoliq,Lcltcalipsoice,Lcltcalipsoun, & Lclhcalipsoliq,Lclhcalipsoice,Lclhcalipsoun, & Lclmcalipsoliq,Lclmcalipsoice,Lclmcalipsoun, & Lcllcalipsoliq,Lcllcalipsoice,Lcllcalipsoun, & LcfadDbze94,Ldbze94,Lparasolrefl,Ltbrttov, & Npoints,Ncolumns,Nlevels,Nlvgrid,Nchan,x) ! Inputs logical,intent(in) :: & Lpctisccp, & ! ISCCP mean cloud top pressure Lclisccp, & ! ISCCP cloud area fraction Lboxptopisccp, & ! ISCCP CTP in each column Lboxtauisccp, & ! ISCCP optical epth in each column Ltauisccp, & ! ISCCP mean optical depth Lcltisccp, & ! ISCCP total cloud fraction Lmeantbisccp, & ! ISCCP mean all-sky 10.5micron brightness temperature Lmeantbclrisccp, & ! ISCCP mean clear-sky 10.5micron brightness temperature Lalbisccp, & ! ISCCP mean cloud albedo LclMISR, & ! MISR cloud fraction Lcltmodis, & ! MODIS total cloud fraction Lclwmodis, & ! MODIS liquid cloud fraction Lclimodis, & ! MODIS ice cloud fraction Lclhmodis, & ! MODIS high-level cloud fraction Lclmmodis, & ! MODIS mid-level cloud fraction Lcllmodis, & ! MODIS low-level cloud fraction Ltautmodis, & ! MODIS total cloud optical thicknes Ltauwmodis, & ! MODIS liquid optical thickness Ltauimodis, & ! MODIS ice optical thickness Ltautlogmodis, & ! MODIS total cloud optical thickness (log10 mean) Ltauwlogmodis, & ! MODIS liquid optical thickness (log10 mean) Ltauilogmodis, & ! MODIS ice optical thickness (log10 mean) Lreffclwmodis, & ! MODIS liquid cloud particle size Lreffclimodis, & ! MODIS ice particle size Lpctmodis, & ! MODIS cloud top pressure Llwpmodis, & ! MODIS cloud liquid water path Liwpmodis, & ! MODIS cloud ice water path Lclmodis, & ! MODIS cloud area fraction Latb532, & ! CALIPSO attenuated total backscatter (532nm) LlidarBetaMol532, & ! CALIPSO molecular backscatter (532nm) LcfadLidarsr532, & ! CALIPSO scattering ratio CFAD Lclcalipso2, & ! CALIPSO cloud fraction undetected by cloudsat Lclcalipso, & ! CALIPSO cloud area fraction Lclhcalipso, & ! CALIPSO high-level cloud fraction Lcllcalipso, & ! CALIPSO low-level cloud fraction Lclmcalipso, & ! CALIPSO mid-level cloud fraction Lcltcalipso, & ! CALIPSO total cloud fraction Lcltlidarradar, & ! CALIPSO-CLOUDSAT total cloud fraction Lclcalipsoliq, & ! CALIPSO liquid cloud area fraction Lclcalipsoice, & ! CALIPSO ice cloud area fraction Lclcalipsoun, & ! CALIPSO undetected cloud area fraction Lclcalipsotmp, & ! CALIPSO undetected cloud area fraction Lclcalipsotmpliq, & ! CALIPSO liquid cloud area fraction Lclcalipsotmpice, & ! CALIPSO ice cloud area fraction Lclcalipsotmpun, & ! CALIPSO undetected cloud area fraction Lcltcalipsoliq, & ! CALIPSO liquid total cloud fraction Lcltcalipsoice, & ! CALIPSO ice total cloud fraction Lcltcalipsoun, & ! CALIPSO undetected total cloud fraction Lclhcalipsoliq, & ! CALIPSO high-level liquid cloud fraction Lclhcalipsoice, & ! CALIPSO high-level ice cloud fraction Lclhcalipsoun, & ! CALIPSO high-level undetected cloud fraction Lclmcalipsoliq, & ! CALIPSO mid-level liquid cloud fraction Lclmcalipsoice, & ! CALIPSO mid-level ice cloud fraction Lclmcalipsoun, & ! CALIPSO mid-level undetected cloud fraction Lcllcalipsoliq, & ! CALIPSO low-level liquid cloud fraction Lcllcalipsoice, & ! CALIPSO low-level ice cloud fraction Lcllcalipsoun, & ! CALIPSO low-level undetected cloud fraction LcfadDbze94, & ! CLOUDSAT radar reflectivity CFAD Ldbze94, & ! CLOUDSAT radar reflectivity LparasolRefl, & ! PARASOL reflectance Ltbrttov ! RTTOV mean clear-sky brightness temperature integer,intent(in) :: & Npoints, & ! Number of sampled points Ncolumns, & ! Number of subgrid columns Nlevels, & ! Number of model levels Nlvgrid, & ! Number of levels in L3 stats computation Nchan ! Number of RTTOV channels ! Outputs type(cosp_outputs),intent(out) :: & x ! COSP output structure ! ISCCP simulator outputs if (Lboxtauisccp) allocate(x%isccp_boxtau(Npoints,Ncolumns)) if (Lboxptopisccp) allocate(x%isccp_boxptop(Npoints,Ncolumns)) if (Lclisccp) allocate(x%isccp_fq(Npoints,numISCCPTauBins,numISCCPPresBins)) if (Lcltisccp) allocate(x%isccp_totalcldarea(Npoints)) if (Lpctisccp) allocate(x%isccp_meanptop(Npoints)) if (Ltauisccp) allocate(x%isccp_meantaucld(Npoints)) if (Lmeantbisccp) allocate(x%isccp_meantb(Npoints)) if (Lmeantbclrisccp) allocate(x%isccp_meantbclr(Npoints)) if (Lalbisccp) allocate(x%isccp_meanalbedocld(Npoints)) ! MISR simulator if (LclMISR) then allocate(x%misr_fq(Npoints,numMISRTauBins,numMISRHgtBins)) ! *NOTE* These 3 fields are not output, but were part of the v1.4.0 cosp_misr, so ! they are still computed. Should probably have a logical to control these ! outputs. allocate(x%misr_dist_model_layertops(Npoints,numMISRHgtBins)) allocate(x%misr_meanztop(Npoints)) allocate(x%misr_cldarea(Npoints)) endif ! MODIS simulator if (Lcltmodis) allocate(x%modis_Cloud_Fraction_Total_Mean(Npoints)) if (Lclwmodis) allocate(x%modis_Cloud_Fraction_Water_Mean(Npoints)) if (Lclimodis) allocate(x%modis_Cloud_Fraction_Ice_Mean(Npoints)) if (Lclhmodis) allocate(x%modis_Cloud_Fraction_High_Mean(Npoints)) if (Lclmmodis) allocate(x%modis_Cloud_Fraction_Mid_Mean(Npoints)) if (Lcllmodis) allocate(x%modis_Cloud_Fraction_Low_Mean(Npoints)) if (Ltautmodis) allocate(x%modis_Optical_Thickness_Total_Mean(Npoints)) if (Ltauwmodis) allocate(x%modis_Optical_Thickness_Water_Mean(Npoints)) if (Ltauimodis) allocate(x%modis_Optical_Thickness_Ice_Mean(Npoints)) if (Ltautlogmodis) allocate(x%modis_Optical_Thickness_Total_LogMean(Npoints)) if (Ltauwlogmodis) allocate(x%modis_Optical_Thickness_Water_LogMean(Npoints)) if (Ltauilogmodis) allocate(x%modis_Optical_Thickness_Ice_LogMean(Npoints)) if (Lreffclwmodis) allocate(x%modis_Cloud_Particle_Size_Water_Mean(Npoints)) if (Lreffclimodis) allocate(x%modis_Cloud_Particle_Size_Ice_Mean(Npoints)) if (Lpctmodis) allocate(x%modis_Cloud_Top_Pressure_Total_Mean(Npoints)) if (Llwpmodis) allocate(x%modis_Liquid_Water_Path_Mean(Npoints)) if (Liwpmodis) allocate(x%modis_Ice_Water_Path_Mean(Npoints)) if (Lclmodis) then allocate(x%modis_Optical_Thickness_vs_Cloud_Top_Pressure(nPoints,numModisTauBins,numMODISPresBins)) allocate(x%modis_Optical_thickness_vs_ReffLIQ(nPoints,numMODISTauBins,numMODISReffLiqBins)) allocate(x%modis_Optical_Thickness_vs_ReffICE(nPoints,numMODISTauBins,numMODISReffIceBins)) endif ! LIDAR simulator if (LlidarBetaMol532) allocate(x%calipso_beta_mol(Npoints,Nlevels)) if (Latb532) allocate(x%calipso_beta_tot(Npoints,Ncolumns,Nlevels)) if (LcfadLidarsr532) then allocate(x%calipso_srbval(SR_BINS+1)) allocate(x%calipso_cfad_sr(Npoints,SR_BINS,Nlvgrid)) allocate(x%calipso_betaperp_tot(Npoints,Ncolumns,Nlevels)) endif if (Lclcalipso) allocate(x%calipso_lidarcld(Npoints,Nlvgrid)) if (Lclhcalipso .or. Lclmcalipso .or. Lcllcalipso .or. Lcltcalipso) then allocate(x%calipso_cldlayer(Npoints,LIDAR_NCAT)) endif if (Lclcalipsoice .or. Lclcalipsoliq .or. Lclcalipsoun) then allocate(x%calipso_lidarcldphase(Npoints,Nlvgrid,6)) endif if (Lclcalipsotmp .or. Lclcalipsotmpliq .or. Lclcalipsoice .or. Lclcalipsotmpun .or. Lclcalipsotmpice) then allocate(x%calipso_lidarcldtmp(Npoints,LIDAR_NTEMP,5)) endif if (Lcllcalipsoice .or. Lclmcalipsoice .or. Lclhcalipsoice .or. & Lcltcalipsoice .or. Lcllcalipsoliq .or. Lclmcalipsoliq .or. & Lclhcalipsoliq .or. Lcltcalipsoliq .or. Lcllcalipsoun .or. & Lclmcalipsoun .or. Lclhcalipsoun .or. Lcltcalipsoun) then allocate(x%calipso_cldlayerphase(Npoints,LIDAR_NCAT,6)) endif ! These 2 outputs are part of the calipso output type, but are not controlled by an ! logical switch in the output namelist, so if all other fields are on, then allocate if (LlidarBetaMol532 .or. Latb532 .or. LcfadLidarsr532 .or. Lclcalipso .or. & Lclcalipsoice .or. Lclcalipsoliq .or. Lclcalipsoun .or. Lclcalipso2 .or. & Lclhcalipso .or. Lclmcalipso .or. Lcllcalipso .or. Lcltcalipso .or. & Lclcalipsotmp .or. Lclcalipsoice .or. Lclcalipsotmpun .or. & Lclcalipsotmpliq .or. Lcllcalipsoice .or. Lclmcalipsoice .or. & Lclhcalipsoice .or. Lcltcalipsoice .or. Lcllcalipsoliq .or. & Lclmcalipsoliq .or. Lclhcalipsoliq .or. Lcltcalipsoliq .or. & Lcllcalipsoun .or. Lclmcalipsoun .or. Lclhcalipsoun .or. Lcltcalipsoun) then allocate(x%calipso_tau_tot(Npoints,Ncolumns,Nlevels)) allocate(x%calipso_temp_tot(Npoints,Nlevels)) endif ! PARASOL if (Lparasolrefl) then allocate(x%parasolPix_refl(Npoints,Ncolumns,PARASOL_NREFL)) allocate(x%parasolGrid_refl(Npoints,PARASOL_NREFL)) endif ! Cloudsat simulator if (Ldbze94) allocate(x%cloudsat_Ze_tot(Npoints,Ncolumns,Nlevels)) if (LcfadDbze94) allocate(x%cloudsat_cfad_ze(Npoints,DBZE_BINS,Nlvgrid)) ! Combined CALIPSO/CLOUDSAT fields if (Lclcalipso2) allocate(x%lidar_only_freq_cloud(Npoints,Nlvgrid)) if (Lcltlidarradar) allocate(x%radar_lidar_tcc(Npoints)) ! RTTOV if (Ltbrttov) allocate(x%rttov_tbs(Npoints,Nchan)) end subroutine construct_cosp_outputs !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cospIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cospIN(y) type(cosp_optical_inputs),intent(inout) :: y if (allocated(y%tau_067)) deallocate(y%tau_067) if (allocated(y%emiss_11)) deallocate(y%emiss_11) if (allocated(y%frac_out)) deallocate(y%frac_out) if (allocated(y%beta_mol)) deallocate(y%beta_mol) if (allocated(y%tau_mol)) deallocate(y%tau_mol) if (allocated(y%betatot)) deallocate(y%betatot) if (allocated(y%betatot_ice)) deallocate(y%betatot_ice) if (allocated(y%betatot_liq)) deallocate(y%betatot_liq) if (allocated(y%tautot)) deallocate(y%tautot) if (allocated(y%tautot_ice)) deallocate(y%tautot_ice) if (allocated(y%tautot_liq)) deallocate(y%tautot_liq) if (allocated(y%tautot_S_liq)) deallocate(y%tautot_S_liq) if (allocated(y%tautot_S_ice)) deallocate(y%tautot_S_ice) if (allocated(y%z_vol_cloudsat)) deallocate(y%z_vol_cloudsat) if (allocated(y%kr_vol_cloudsat)) deallocate(y%kr_vol_cloudsat) if (allocated(y%g_vol_cloudsat)) deallocate(y%g_vol_cloudsat) if (allocated(y%asym)) deallocate(y%asym) if (allocated(y%ss_alb)) deallocate(y%ss_alb) if (allocated(y%fracLiq)) deallocate(y%fracLiq) end subroutine destroy_cospIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cospstateIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cospstateIN(y) type(cosp_column_inputs),intent(inout) :: y if (allocated(y%sunlit)) deallocate(y%sunlit) if (allocated(y%skt)) deallocate(y%skt) if (allocated(y%land)) deallocate(y%land) if (allocated(y%at)) deallocate(y%at) if (allocated(y%pfull)) deallocate(y%pfull) if (allocated(y%phalf)) deallocate(y%phalf) if (allocated(y%qv)) deallocate(y%qv) if (allocated(y%o3)) deallocate(y%o3) if (allocated(y%hgt_matrix)) deallocate(y%hgt_matrix) if (allocated(y%u_sfc)) deallocate(y%u_sfc) if (allocated(y%v_sfc)) deallocate(y%v_sfc) if (allocated(y%lat)) deallocate(y%lat) if (allocated(y%lon)) deallocate(y%lon) if (allocated(y%emis_sfc)) deallocate(y%emis_sfc) if (allocated(y%cloudIce)) deallocate(y%cloudIce) if (allocated(y%cloudLiq)) deallocate(y%cloudLiq) if (allocated(y%seaice)) deallocate(y%seaice) if (allocated(y%fl_rain)) deallocate(y%fl_rain) if (allocated(y%fl_snow)) deallocate(y%fl_snow) if (allocated(y%tca)) deallocate(y%tca) if (allocated(y%hgt_matrix_half)) deallocate(y%hgt_matrix_half) end subroutine destroy_cospstateIN !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! SUBROUTINE destroy_cosp_outputs !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% subroutine destroy_cosp_outputs(y) type(cosp_outputs),intent(inout) :: y ! Deallocate and nullify if (associated(y%calipso_beta_mol)) then deallocate(y%calipso_beta_mol) nullify(y%calipso_beta_mol) endif if (associated(y%calipso_temp_tot)) then deallocate(y%calipso_temp_tot) nullify(y%calipso_temp_tot) endif if (associated(y%calipso_betaperp_tot)) then deallocate(y%calipso_betaperp_tot) nullify(y%calipso_betaperp_tot) endif if (associated(y%calipso_beta_tot)) then deallocate(y%calipso_beta_tot) nullify(y%calipso_beta_tot) endif if (associated(y%calipso_tau_tot)) then deallocate(y%calipso_tau_tot) nullify(y%calipso_tau_tot) endif if (associated(y%calipso_lidarcldphase)) then deallocate(y%calipso_lidarcldphase) nullify(y%calipso_lidarcldphase) endif if (associated(y%calipso_cldlayerphase)) then deallocate(y%calipso_cldlayerphase) nullify(y%calipso_cldlayerphase) endif if (associated(y%calipso_lidarcldtmp)) then deallocate(y%calipso_lidarcldtmp) nullify(y%calipso_lidarcldtmp) endif if (associated(y%calipso_cldlayer)) then deallocate(y%calipso_cldlayer) nullify(y%calipso_cldlayer) endif if (associated(y%calipso_lidarcld)) then deallocate(y%calipso_lidarcld) nullify(y%calipso_lidarcld) endif if (associated(y%calipso_srbval)) then deallocate(y%calipso_srbval) nullify(y%calipso_srbval) endif if (associated(y%calipso_cfad_sr)) then deallocate(y%calipso_cfad_sr) nullify(y%calipso_cfad_sr) endif if (associated(y%parasolPix_refl)) then deallocate(y%parasolPix_refl) nullify(y%parasolPix_refl) endif if (associated(y%parasolGrid_refl)) then deallocate(y%parasolGrid_refl) nullify(y%parasolGrid_refl) endif if (associated(y%cloudsat_Ze_tot)) then deallocate(y%cloudsat_Ze_tot) nullify(y%cloudsat_Ze_tot) endif if (associated(y%cloudsat_cfad_ze)) then deallocate(y%cloudsat_cfad_ze) nullify(y%cloudsat_cfad_ze) endif if (associated(y%radar_lidar_tcc)) then deallocate(y%radar_lidar_tcc) nullify(y%radar_lidar_tcc) endif if (associated(y%lidar_only_freq_cloud)) then deallocate(y%lidar_only_freq_cloud) nullify(y%lidar_only_freq_cloud) endif if (associated(y%isccp_totalcldarea)) then deallocate(y%isccp_totalcldarea) nullify(y%isccp_totalcldarea) endif if (associated(y%isccp_meantb)) then deallocate(y%isccp_meantb) nullify(y%isccp_meantb) endif if (associated(y%isccp_meantbclr)) then deallocate(y%isccp_meantbclr) nullify(y%isccp_meantbclr) endif if (associated(y%isccp_meanptop)) then deallocate(y%isccp_meanptop) nullify(y%isccp_meanptop) endif if (associated(y%isccp_meantaucld)) then deallocate(y%isccp_meantaucld) nullify(y%isccp_meantaucld) endif if (associated(y%isccp_meanalbedocld)) then deallocate(y%isccp_meanalbedocld) nullify(y%isccp_meanalbedocld) endif if (associated(y%isccp_boxtau)) then deallocate(y%isccp_boxtau) nullify(y%isccp_boxtau) endif if (associated(y%isccp_boxptop)) then deallocate(y%isccp_boxptop) nullify(y%isccp_boxptop) endif if (associated(y%isccp_fq)) then deallocate(y%isccp_fq) nullify(y%isccp_fq) endif if (associated(y%misr_fq)) then deallocate(y%misr_fq) nullify(y%misr_fq) endif if (associated(y%misr_dist_model_layertops)) then deallocate(y%misr_dist_model_layertops) nullify(y%misr_dist_model_layertops) endif if (associated(y%misr_meanztop)) then deallocate(y%misr_meanztop) nullify(y%misr_meanztop) endif if (associated(y%misr_cldarea)) then deallocate(y%misr_cldarea) nullify(y%misr_cldarea) endif if (associated(y%rttov_tbs)) then deallocate(y%rttov_tbs) nullify(y%rttov_tbs) endif if (associated(y%modis_Cloud_Fraction_Total_Mean)) then deallocate(y%modis_Cloud_Fraction_Total_Mean) nullify(y%modis_Cloud_Fraction_Total_Mean) endif if (associated(y%modis_Cloud_Fraction_Ice_Mean)) then deallocate(y%modis_Cloud_Fraction_Ice_Mean) nullify(y%modis_Cloud_Fraction_Ice_Mean) endif if (associated(y%modis_Cloud_Fraction_Water_Mean)) then deallocate(y%modis_Cloud_Fraction_Water_Mean) nullify(y%modis_Cloud_Fraction_Water_Mean) endif if (associated(y%modis_Cloud_Fraction_High_Mean)) then deallocate(y%modis_Cloud_Fraction_High_Mean) nullify(y%modis_Cloud_Fraction_High_Mean) endif if (associated(y%modis_Cloud_Fraction_Mid_Mean)) then deallocate(y%modis_Cloud_Fraction_Mid_Mean) nullify(y%modis_Cloud_Fraction_Mid_Mean) endif if (associated(y%modis_Cloud_Fraction_Low_Mean)) then deallocate(y%modis_Cloud_Fraction_Low_Mean) nullify(y%modis_Cloud_Fraction_Low_Mean) endif if (associated(y%modis_Optical_Thickness_Total_Mean)) then deallocate(y%modis_Optical_Thickness_Total_Mean) nullify(y%modis_Optical_Thickness_Total_Mean) endif if (associated(y%modis_Optical_Thickness_Water_Mean)) then deallocate(y%modis_Optical_Thickness_Water_Mean) nullify(y%modis_Optical_Thickness_Water_Mean) endif if (associated(y%modis_Optical_Thickness_Ice_Mean)) then deallocate(y%modis_Optical_Thickness_Ice_Mean) nullify(y%modis_Optical_Thickness_Ice_Mean) endif if (associated(y%modis_Optical_Thickness_Total_LogMean)) then deallocate(y%modis_Optical_Thickness_Total_LogMean) nullify(y%modis_Optical_Thickness_Total_LogMean) endif if (associated(y%modis_Optical_Thickness_Water_LogMean)) then deallocate(y%modis_Optical_Thickness_Water_LogMean) nullify(y%modis_Optical_Thickness_Water_LogMean) endif if (associated(y%modis_Optical_Thickness_Ice_LogMean)) then deallocate(y%modis_Optical_Thickness_Ice_LogMean) nullify(y%modis_Optical_Thickness_Ice_LogMean) endif if (associated(y%modis_Cloud_Particle_Size_Water_Mean)) then deallocate(y%modis_Cloud_Particle_Size_Water_Mean) nullify(y%modis_Cloud_Particle_Size_Water_Mean) endif if (associated(y%modis_Cloud_Particle_Size_Ice_Mean)) then deallocate(y%modis_Cloud_Particle_Size_Ice_Mean) nullify(y%modis_Cloud_Particle_Size_Ice_Mean) endif if (associated(y%modis_Cloud_Top_Pressure_Total_Mean)) then deallocate(y%modis_Cloud_Top_Pressure_Total_Mean) nullify(y%modis_Cloud_Top_Pressure_Total_Mean) endif if (associated(y%modis_Liquid_Water_Path_Mean)) then deallocate(y%modis_Liquid_Water_Path_Mean) nullify(y%modis_Liquid_Water_Path_Mean) endif if (associated(y%modis_Ice_Water_Path_Mean)) then deallocate(y%modis_Ice_Water_Path_Mean) nullify(y%modis_Ice_Water_Path_Mean) endif if (associated(y%modis_Optical_Thickness_vs_Cloud_Top_Pressure)) then deallocate(y%modis_Optical_Thickness_vs_Cloud_Top_Pressure) nullify(y%modis_Optical_Thickness_vs_Cloud_Top_Pressure) endif if (associated(y%modis_Optical_thickness_vs_ReffLIQ)) then deallocate(y%modis_Optical_thickness_vs_ReffLIQ) nullify(y%modis_Optical_thickness_vs_ReffLIQ) endif if (associated(y%modis_Optical_thickness_vs_ReffICE)) then deallocate(y%modis_Optical_thickness_vs_ReffICE) nullify(y%modis_Optical_thickness_vs_ReffICE) endif end subroutine destroy_cosp_outputs !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% ! END MODULE !%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% end module MOD_COSP_INTERFACE_v1p4