def __init__(self): documentation = get_special_documentation() brdf_non_parents=['albedo','albedo_file','albedo_library', 'brdf_rossli', 'brdf_rossli_file', 'brdf_rossli_hotspot', 'brdf_cam', 'brdf_cam_solar_wind', 'cox_and_munk_u10_map', 'brdf_rpv_file', 'brdf_rpv', 'brdf_rpv_library','brdf_rpv_type', 'brdf_hapke', 'brdf_hapke_file', 'mc_albedo_file', 'mc_rossli_file', 'mc_rpv_type', 'mc_rpv_file','mc_rpv_spectral_file', 'mc_ambrals_type', 'mc_ambrals_spectral_file', 'bpdf_tsang_u10'] albedo_library = option_definition.option( name='albedo_library', group='special', helpstr='Spectral albedos of different surface types.', documentation=documentation['albedo_library'], tokens=option_definition.addToken(name='Input.alb.library', datatype=str, valid_range=['IGBP',io.IOBase]), parents=['uvspec'], non_parents=brdf_non_parents, childs=['brdf_rpv_type'], showInGui = False ) cloud_fraction_map = option_definition.option( name='cloud_fraction_map', group='special', documentation=documentation['cloud_fraction_map'], tokens=option_definition.addToken(name='Input.filename[FN_CLOUD_FRACTION_MAP]',datatype=io.IOBase), developer=True, ) albedo_map = option_definition.option( name='albedo_map', group='special', documentation=documentation['albedo_map'], tokens=[option_definition.addSetting(name='Input.alb.source', setting='ALBEDO_FROM_ALBEDO_MAP') , option_definition.addToken(name='Input.filename[FN_ALBEDO_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.alb.netCDF_alb_name',datatype=io.IOBase,optional=True), option_definition.addToken(name='Input.alb.scale_factor',datatype=float,optional=True)], developer=True ) altitude_map = option_definition.option( name='altitude_map', group='special', documentation=documentation['altitude_map'], tokens=[option_definition.addSetting(name='Input.alt.source', setting='ALT_FROM_MAP') , option_definition.addToken(name='Input.filename[FN_ALTITUDE_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.alt.netCDF_alt_name',datatype=io.IOBase,optional=True), option_definition.addToken(name='Input.alt.scale_factor',datatype=float,optional=True)], developer=True ) cox_and_munk_u10_map = option_definition.option( name='cox_and_munk_u10_map', group='special', helpstr='Location of netCDF file with wind speed for ocean BRDF.', documentation=documentation['cox_and_munk_u10_map'], tokens = [option_definition.addToken(name='Input.filename[FN_U10_MAP]', datatype=io.IOBase), option_definition.addSetting(name='Input.disort2_brdf', setting='BRDF_CAM', default='BRDF_NONE')], parents=['uvspec'], non_parents=brdf_non_parents, non_parent_exceptions=['brdf_cam', 'brdf_cam_solar_wind', 'cox_and_munk_u10_map', 'mc_rossli_file'], showInGui= False, developer=True ) cox_and_munk_pcl_map = option_definition.option( name='cox_and_munk_pcl_map', group='special', documentation=documentation['cox_and_munk_pcl_map'], tokens=[option_definition.addSetting(name='Input.disort2_brdf', setting='BRDF_CAM') , option_definition.addToken(name='Input.filename[FN_PIGMENTS_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.cm.pcl_netCDF_name',datatype=io.IOBase,optional=True), option_definition.addToken(name='Input.cm.pcl_scale_factor',datatype=float,optional=True)], developer=True ) cox_and_munk_sal_map = option_definition.option( name='cox_and_munk_sal_map', group='special', documentation=documentation['cox_and_munk_sal_map'], tokens=[option_definition.addSetting(name='Input.disort2_brdf', setting='BRDF_CAM') , option_definition.addToken(name='Input.filename[FN_SALINITY_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.cm.sal_netCDF_name',datatype=io.IOBase,optional=True), option_definition.addToken(name='Input.cm.sal_scale_factor',datatype=float,optional=True)], developer=True ) emissivity_map = option_definition.option( name='emissivity_map', group='special', documentation=documentation['emissivity_map'], tokens=[option_definition.addSetting(name='Input.alb.source', setting='ALBEDO_FROM_EMISSIVITY_MAP') , option_definition.addToken(name='Input.filename[FN_ALBEDO_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.alb.netCDF_alb_name',datatype=io.IOBase,optional=True), option_definition.addToken(name='Input.alb.scale_factor',datatype=float,optional=True)], developer=True ) surface_temperature_map = option_definition.option( name='surface_temperature_map', group='special', documentation=documentation['surface_temperature_map'], tokens=[option_definition.addToken(name='Input.filename[FN_SURFACE_TEMP_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.netCDF_name_surf_T',datatype=io.IOBase,optional=True)], developer=True ) surface_type_map = option_definition.option( name='surface_type_map', group='special', documentation=documentation['surface_type_map'], tokens=[option_definition.addSetting(name='Input.alb.surf_type_map',setting='TRUE'), option_definition.addToken(name='Input.filename[FN_SURFACE_TYPE_MAP]',datatype=io.IOBase), option_definition.addToken(name='Input.alb.netCDF_surf_name',datatype=io.IOBase,optional=True)] ) ECHAM_sza = option_definition.option( name='ECHAM_sza', group='special', documentation=documentation['ECHAM_sza'], tokens=[option_definition.addToken(name='Input.filename[FN_SZA]',datatype=io.IOBase), option_definition.addSetting(name='Input.atm.sza',setting='NOT_DEFINED_FLOAT'), option_definition.addSetting(name='Input.atm.sza_source',setting='SZA_ECHAM')], developer=True, ) ECMWF_ozone_climatology = option_definition.option( name='ECMWF_ozone_climatology', group='special', documentation=documentation['ECMWF_ozone_climatology'], tokens=option_definition.addSetting(name='Input.atm.ECMWF_ozone_climatology',setting='TRUE'), developer=True ) ECMWF_wc_file = option_definition.option( name='ECMWF_wc_file', group='special', documentation=documentation['ECMWF_wc_file'], tokens=[option_definition.addSetting(name='isp',setting=option_definition.CaothType('wc')), option_definition.addSetting(name='Input.caoth[isp].source',setting='CAOTH_FROM_ECMWF'), option_definition.addToken(name='Input.caoth[isp].filename',datatype=io.IOBase)], developer=True ) ECMWF_ic_file = option_definition.option( name='ECMWF_ic_file', group='special', documentation=documentation['ECMWF_ic_file'], tokens=[option_definition.addSetting(name='isp',setting=option_definition.CaothType('ic')), option_definition.addSetting(name='Input.caoth[isp].source',setting='CAOTH_FROM_ECMWF'), option_definition.addToken(name='Input.caoth[isp].filename',datatype=io.IOBase)], developer=True ) ECMWF_levels_only = option_definition.option( name='ECMWF_levels_only', group='special', documentation=documentation['ECMWF_levels_only'], tokens=option_definition.addSetting(name='Input.atm.rs_add_upper_levels',setting='FALSE'), developer=True ) ECMWF_wind_file = option_definition.option( name='ECMWF_wind_file', group='special', documentation=documentation['ECMWF_wind_file'], tokens=option_definition.addToken(name='Input.filename[FN_ECMWF_WIND_MAP]',datatype=io.IOBase), developer=True ) satellite_geometry = option_definition.option( name='satellite_geometry', group='special', documentation=documentation['satellite_geometry'], tokens=option_definition.addToken(name='Input.filename[FN_SATGEOMETRY]',datatype=io.IOBase), developer=True ) satellite_pixel = option_definition.option( name='satellite_pixel', group='special', documentation=documentation['satellite_pixel'], tokens=[option_definition.addToken(name='Input.sat_pixel_x',datatype=int), option_definition.addToken(name='Input.sat_pixel_y',datatype=int)], developer=True ) self.options = [ ECHAM_sza, ECMWF_ozone_climatology, ECMWF_wc_file, ECMWF_ic_file, ECMWF_wind_file, ECMWF_levels_only, cox_and_munk_u10_map, cox_and_munk_pcl_map, cox_and_munk_sal_map, cloud_fraction_map, altitude_map, albedo_map, emissivity_map, surface_temperature_map, surface_type_map, albedo_library, satellite_geometry, satellite_pixel, ] #Special group belongs to developers options; should not be in Gui for EsasLight version; for opt in self.options: opt.showInGui = False
def __init__(self): documentation = get_output_documentation() include = option_definition.not_yet_lex2py_option( name='include', group='output', helpstr='Include a file into uvspec input.', documentation=documentation['include'], gui_inputs=(GUI_definition.FileInput(name='filename'),), parents=['uvspec'], showInGui=False, ) quiet = option_definition.option( name='quiet', group='output', helpstr='If specified, informative messages are turned off. See also \code{verbose}.', documentation=documentation['quiet'], tokens=option_definition.addSetting(name='Input.quiet', setting=1, default=0), parents=['uvspec'], non_parents=['verbose'], ) verbose = option_definition.option( name='verbose', group='output', helpstr='If specified abundances of informative messages are output to stderr.', documentation=documentation['verbose'], tokens=option_definition.addSetting(name='Input.verbose', setting=1, default=0), parents=['uvspec'], non_parents=['quiet'], ) write_ext_to_file = option_definition.option( name='write_ext_to_file', group='output', helpstr='If specified abundances of informative messages are output to stderr.', documentation=documentation['write_ext_to_file'], tokens=option_definition.addSetting(name='Input.write_ext_to_file', setting=1, default=0), parents=['uvspec'], islidar=True, ) test_optical_properties = option_definition.option( name='test_optical_properties', group='output', helpstr='Write optical properties to file without solving RTE.', documentation=documentation['test_optical_properties'], tokens=option_definition.addSetting(name='Input.test_optical_properties', setting=1, default=0), parents=['uvspec'], developer=True, ) print_disort_info = option_definition.option( name='print_disort_info', group='output', helpstr='Print various disort output. See disort.doc', documentation=documentation['print_disort_info'], tokens=[option_definition.addToken(name="Input.rte.prndis", datatype=option_definition.Integers), option_definition.addSetting(name='Input.rte.nprndis',setting='ntokens')], ) data_files_path = option_definition.option( name='data_files_path', group='output', documentation=documentation['data_files_path'], gui_inputs=(GUI_definition.FileInput(name='Input.filename[FN_PATH]'),), tokens = option_definition.addToken(name='Input.filename[FN_PATH]' , datatype=io.IOBase), ) output_process = option_definition.option( name='output_process', group='output', helpstr='Decide how the output from \code{uvspec} is processed.', documentation=documentation['output_process'], gui_inputs=(GUI_definition.ListInput(name='Input.output_unit_processing', valid_range=['integrate', 'sum', 'rgbnorm', 'rgb_norm', 'rgb', 'per_nm', 'per_cm-1', 'per_band'], optional=False),), tokens=option_definition.addToken(name='Input.output_unit_processing', datatype=str, valid_range=['integrate','sum','rgbnorm','rgb_norm','rgb', 'per_nm','per_cm-1','per_band']), parents=['uvspec'], ) output_file = option_definition.option( name='output_file', group='output', helpstr='Location of the output file', documentation=documentation['output_file'], gui_inputs=(GUI_definition.TextInput(name='Input.filename[FN_OUTFILE]'),), tokens=option_definition.addToken(name='Input.filename[FN_OUTFILE]', datatype=str), parents=['uvspec'], ) output_format = option_definition.option( name='output_format', group='output', helpstr='Output format', documentation=documentation['output_format'], tokens=option_definition.addLogical(name='Input.output_format', logicals=['ascii','flexstor','netCDF','sat_picture'], setting='OUTPUT_FORMAT_'), ) output_user = option_definition.not_yet_lex2py_option( name='output_user', group='output', helpstr='User defined output', documentation=documentation['output_user'], gui_inputs=(GUI_definition.TextInput(name=''),), tokens=option_definition.addToken(name="", datatype=str), parents=['uvspec'], ) output_quantity = option_definition.option( name='output_quantity', group='output', helpstr='Define output quantity to calculate instead of absolute quantities.', documentation=documentation['output_quantity'], tokens=option_definition.addLogical(name='Input.calibration', logicals=['reflectivity','transmittance','brightness'], setting='OUTCAL_'), parents=['uvspec'], ) heating_rate = option_definition.option( name='heating_rate', group='output', helpstr='Calculation of heating rates.', documentation=documentation['heating_rate'], gui_inputs=(GUI_definition.ListInput(name='Input.heating', valid_range=['none', 'local', 'layer_fd', 'layer_cd'], optional=True),), tokens = [option_definition.addSetting(name='Input.heating', setting='HEAT_LAYER_CD'), option_definition.addLogical(name='Input.heating', logicals=['none','local','layer_fd','layer_cd'], setting='HEAT_', optional=True) ] , parents=['uvspec'], ) write_output_as_netcdf = option_definition.option( name='write_output_as_netcdf', group='output', helpstr='Output is written into netcdf file.', documentation=documentation['write_output_as_netcdf'], tokens=option_definition.addSetting(name='Input.write_output_as_netcdf', setting=1), parents=['uvspec'], islidar=True, showInGui=False, ) slit_function_file = option_definition.option( name='slit_function_file', group='output', helpstr='If specified, the calculated spectrum is convolved with the function found in the slit_function_file.', documentation=documentation['slit_function_file'], gui_inputs=(GUI_definition.FileInput(name='Input.filename[FN_SLITFUNCTION]'),), tokens = [option_definition.addToken(name='Input.filename[FN_SLITFUNCTION]', datatype=io.IOBase), option_definition.addSetting(name='Input.convolve', setting=1, default=0)], parents=['uvspec'], non_parents=['filter_function_file','thermal_bands_file'], plot = {'plot_type': '2D', 'optional_args': {'column_names': ( "wavelength", "slit function",) } } ) spline = option_definition.option( name='spline', group='output', helpstr='Spline interpolate the calculated spectrum.', documentation=documentation['spline'], gui_inputs=(GUI_definition.FloatInput(name='Input.spline_lambda_0', valid_range=[0, 1000000.0]), GUI_definition.FloatInput(name='Input.spline_lambda_1', valid_range=[0, 1000000.0]), GUI_definition.FloatInput(name='Input.spline_lambda_step', valid_range=[0, 1000000.0]),), tokens = [option_definition.addToken(name='Input.spline_lambda_0', datatype=float, valid_range=[0,1e6]), #TODO:Valid_range from option wavelength. option_definition.addToken(name='Input.spline_lambda_1', datatype=float, valid_range=[0,1e6]), option_definition.addToken(name='Input.spline_lambda_step', datatype=float, valid_range=[0,1e6]), option_definition.addSetting(name='Input.spline', setting=1, default=0)], parents=['uvspec'], non_parents=['spline_file'], ) spline_file = option_definition.option( name='spline_file', group='output', helpstr='Spline interpolate to arbitrary wavelengths, in nm, given as a single column in file.', documentation=documentation['spline_file'], gui_inputs=(GUI_definition.FileInput(name='Input.filename[FN_SPLINE]'),), tokens = [option_definition.addToken(name='Input.filename[FN_SPLINE]', datatype=io.IOBase), option_definition.addSetting(name='Input.spline', setting=1, default=0) ] , parents=['uvspec'], non_parents=['spline'], ) filter_function_file = option_definition.option( name='filter_function_file', group='output', helpstr='If specified, the calculated spectrum is multiplied with a filter function defined in file.', documentation=documentation['filter_function_file'], tokens=[option_definition.addToken(name='Input.filename[FN_FILTERFUNCTION]',datatype=io.IOBase), option_definition.addLogical(name='Input.filter_function_normalize', logicals=['normalize'], optional=True)], parents=['uvspec'], non_parents=['slit_function_file','thermal_bands_file'], plot = {'plot_type': '2D', 'optional_args': {'column_names': ( "wavelength", "filter function",) } } ) pressure_out = option_definition.not_yet_lex2py_option( name='pressure_out', group='output', helpstr='Specify the output levels in pressure coordinates.', documentation=documentation['pressure_out'], gui_inputs=(GUI_definition.TextInput(name=''),), parents=['uvspec'], non_parents=['zout','zout_sea'], ) zout = option_definition.not_yet_lex2py_option( name='zout', group='output', helpstr='Output altitude(s).', documentation=documentation['zout'], gui_inputs=(GUI_definition.TextInput(name=''),), tokens=option_definition.addToken(name="", datatype=str), parents=['uvspec'], non_parents=['zout_sea','pressure_out'], ) zout_sea = option_definition.not_yet_lex2py_option( name='zout_sea', group='output', helpstr='Output altitude(s) above sea surface.', documentation=documentation['zout_sea'], gui_inputs=(GUI_definition.TextInput(name=''),), tokens=option_definition.addToken(name="", datatype=str), parents=['uvspec'], non_parents=['zout','pressure_out'], ) mc_backward_output = option_definition.option( name='mc_backward_output', group='output', helpstr='Specify quantity to be calculated using backward Monte Carlo.', documentation=documentation['mc_backward_output'], tokens=[option_definition.addLogical(name='Input.rte.mc.backward.output', logicals=['edir','edn','eup','fdir','fdn','fup','act','abs','emis','heat','exp','exn','eyp','eyn','ednpv'], setting='MCBACKWARD_', gui_name='output'), option_definition.addLogical(name='Input.rte.mc.abs_unit', logicals=['W_per_m2_and_dz', 'W_per_m3', 'K_per_day'], setting='MCABS_UNIT_' , optional = True, gui_name='unit')], parents=['mc_backward'], speaker='rte_solver', enable_values=("mystic","montecarlo"), mystic =True ) mc_forward_output = option_definition.option( name='mc_forward_output', group='output', helpstr='Specify quantity to be calculated using forward Monte Carlo.', documentation=documentation['mc_forward_output'], tokens = [option_definition.addLogical(name='Input.rte.mc.absorption', logicals=['absorption','actinic','emission','heating'], setting='MCFORWARD_ABS_', gui_name='output'), option_definition.addLogical(name='Input.rte.mc.abs_unit', logicals=['W_per_m2_and_dz', 'W_per_m3', 'K_per_day'] , setting='MCABS_UNIT_', optional = True, gui_name='unit')], parents=['uvspec'], non_parents=['mc_backward'], speaker='rte_solver', enable_values=("mystic","montecarlo"), mystic =True ) mc_basename = option_definition.option( name='mc_basename', group='output', helpstr='Filename for MYSTIC output.', documentation=documentation['mc_basename'], tokens=option_definition.addToken(name='Input.rte.mc.filename[FN_MC_BASENAME]',datatype=io.IOBase), parents=['uvspec'], speaker='rte_solver', enable_values=("mystic","montecarlo"), mystic =True ) mc_backward_writeallpixels = option_definition.option( name='mc_backward_writeallpixels', group='output', helpstr='Write all pixels to the output files', documentation=documentation['mc_backward_writeallpixels'], tokens=option_definition.addSetting(name='Input.rte.mc.backward.writeallpixels', setting=1), parents=['mc_backward'], speaker='rte_solver', enable_values=("mystic","montecarlo"), threedmystic =True ) mc_std = option_definition.option( name='mc_std', group='output', helpstr='Calculate MYSTIC standard deviation.', documentation=documentation['mc_std'], tokens=option_definition.addSetting(name='Input.rte.mc.std', setting=1, default=0), parents=['uvspec'], speaker='rte_solver', enable_values=("mystic","montecarlo"), threedmystic =True ) mc_surfaceparallel = option_definition.option( name='mc_surfaceparallel', group='output', helpstr='Calculate irradiance parallel to the surface.', documentation=documentation['mc_surfaceparallel'], tokens=option_definition.addSetting(name='Input.rte.mc.surfaceparallel', setting=1), parents=['uvspec'], speaker='rte_solver', enable_values=("mystic","montecarlo"), threedmystic =True, showInGui=False, ) mc_jacobian = option_definition.option( name='mc_jacobian', group='output', helpstr='Calculate jacobi matrix.', documentation=documentation['mc_jacobian'], tokens=option_definition.addSetting(name='Input.rte.mc.jacobian', setting=1), parents=['uvspec'], childs=['mc_jacobian_std'], speaker='rte_solver', enable_values=("mystic","montecarlo"), threedmystic =False, islidar=False, showInGui=False, developer=True ) mc_jacobian_std = option_definition.option( name='mc_jacobian_std', group='output', helpstr='Calculate jacobi matrix standard deviation.', documentation=documentation['mc_jacobian_std'], tokens=option_definition.addSetting(name='Input.rte.mc.jacobian_std', setting=1), parents=['mc_jacobian'], speaker='rte_solver', enable_values=("mystic","montecarlo"), threedmystic =True, islidar=True, showInGui=False, developer=True ) self.options = [include, quiet, verbose, write_ext_to_file, test_optical_properties, print_disort_info, data_files_path, output_process, output_file, output_format, output_user, output_quantity, heating_rate, write_output_as_netcdf, slit_function_file, spline, spline_file, filter_function_file, pressure_out, zout, zout_sea, mc_backward_output, mc_forward_output, mc_basename, mc_backward_writeallpixels, mc_std, mc_surfaceparallel, mc_jacobian, mc_jacobian_std, ]
def __init__(self): documentation = get_geometry_documentation() sza = option_definition.option( name='sza', group='geometry', helpstr='Solar zenith angle', documentation=documentation['sza'], tokens=[ option_definition.addToken(name='Input.atm.sza', datatype=float, default='NOT_DEFINED_FLOAT', valid_range=[0., 180.]), option_definition.addSetting( name='Input.atm.sza_source', setting='SZA_DIRECT_INPUT', default='SZA_BY_TIME_AND_LOCATION') ], parents=['uvspec'], non_parents=['sza_file', 'ECHAM_sza'], ) sza_file = option_definition.option( name='sza_file', group='geometry', helpstr='Location of solar zenith angle file.', documentation=documentation['sza_file'], tokens=[ option_definition.addToken(name='Input.filename[FN_SZA]', datatype=io.IOBase), option_definition.addSetting( name='Input.atm.sza_source', setting='SZA_FROM_SZA_FILE', default='SZA_BY_TIME_AND_LOCATION') ], parents=['uvspec'], non_parents=['sza', 'ECHAM_sza'], ) phi0 = option_definition.option( name='phi0', group='geometry', helpstr='Solar azimuth angle', documentation=documentation['phi0'], tokens=option_definition.addToken(name='Input.atm.phi0', datatype=float, valid_range=[-360., 360.]), parents=['uvspec'], ) phi = option_definition.option( name='phi', group='geometry', helpstr='User output azimuth angles.', documentation=documentation['phi'], tokens=[ option_definition.addToken( name='Input.rte.phi', datatype=option_definition.SignedFloats), option_definition.addSetting(name='Input.rte.nphi', setting='ntokens'), option_definition.addSetting(name='Input.rte.maxphi', setting='ntokens') ], parents=['uvspec'], ) umu = option_definition.option( name='umu', group='geometry', helpstr='Cosine of user output polar angles.', documentation=documentation['umu'], tokens=[ option_definition.addToken( name='Input.rte.umu', datatype=option_definition.SignedFloats), option_definition.addSetting(name='Input.rte.numu', setting='ntokens'), option_definition.addSetting(name='Input.rte.maxumu', setting='ntokens') ], parents=['uvspec'], non_parents=[], childs=[]) mc_bw_umu_file = option_definition.option( name='mc_bw_umu_file', group='geometry', helpstr='Define a different umu and phi for each pixel.', documentation=documentation['mc_bw_umu_file'], gui_inputs=(GUI_definition.FileInput(name='filename'), ), tokens=[ option_definition.addToken( name="Input.rte.mc.filename[FN_MC_UMU]", datatype=io.IOBase), option_definition.addSetting( name='Input.rte.mc.allocate_umu_and_phi', setting=True) ], parents=['mc_backward'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True) earth_radius = option_definition.option( name='earth_radius', group='geometry', helpstr='Radius of the Earth in km', documentation=documentation['earth_radius'], tokens=option_definition.addToken(name='Input.r_earth', datatype=float, default=6370.0), parents=['uvspec'], ) latitude = option_definition.option( name='latitude', group='geometry', helpstr='Specify the latitude of the location to simulate.', documentation=documentation['latitude'], gui_inputs=( GUI_definition.ListInput(name='hemisphere', valid_range=['n', 's']), GUI_definition.FloatInput(name='degrees', valid_range=[0, 180]), GUI_definition.FloatInput(name='minutes', valid_range=[0, 60], optional=True), GUI_definition.FloatInput(name='seconds', valid_range=[0, 60], optional=True), ), tokens=[ option_definition.addLogical(name='Input.lat_signum', logicals=['n', 's'], setting='LATITUDE_SIGNUM_'), option_definition.addToken(name='Input.lat_degrees', datatype=float), option_definition.addToken(name='Input.lat_minutes', datatype=float, optional=True), option_definition.addToken(name='Input.lat_seconds', datatype=float, optional=True) ], parents=['uvspec'], extra_dependencies=['latitude', 'longitude'], showInGui=False) longitude = option_definition.option( name='longitude', group='geometry', helpstr='Specify the longitude of the location to simulate.', documentation=documentation['longitude'], gui_inputs=( GUI_definition.ListInput(name='hemisphere', valid_range=['e', 'w']), GUI_definition.FloatInput(name='degrees', valid_range=[0, 180]), GUI_definition.FloatInput(name='minutes', valid_range=[0, 60], optional=True), GUI_definition.FloatInput(name='seconds', valid_range=[0, 60], optional=True), ), tokens=[ option_definition.addLogical(name='Input.lon_signum', logicals=['e', 'w'], setting='LONGITUDE_SIGNUM_'), option_definition.addToken(name='Input.lon_degrees', datatype=float), option_definition.addToken(name='Input.lon_minutes', datatype=float, optional=True), option_definition.addToken(name='Input.lon_seconds', datatype=float, optional=True) ], parents=['uvspec'], extra_dependencies=['latitude', 'longitude'], showInGui=False, ) day_of_year = option_definition.option( name='day_of_year', group='geometry', helpstr='Correction fo sun-earth distance', documentation=documentation['day_of_year'], tokens=option_definition.addToken(name='Input.UTC.tm_yday', datatype=int, default='NOT_DEFINED_INTEGER'), parents=['uvspec'], ) mc_bcond = option_definition.option( name='mc_bcond', group='geometry', helpstr='Define MYSTIC boundary conditions.', documentation=documentation['mc_bcond'], tokens=option_definition.addLogical( name='Input.rte.mc.bcond', logicals=['periodic', 'mirror', 'absorb'], setting='MCBCOND_'), parents=['uvspec'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), mystic=True, developer=True, showInGui=False, ) mc_sample_grid = option_definition.option( name='mc_sample_grid', group='geometry', helpstr='Sample grid size (Nx Ny [dx dy]) for MYSTIC.', documentation=documentation['mc_sample_grid'], tokens=[ option_definition.addToken(name="Input.rte.mc.Nx_sample", datatype=int), option_definition.addToken(name="Input.rte.mc.Ny_sample", datatype=int), option_definition.addToken(name="Input.rte.mc.dx_sample", datatype=float, optional=True), option_definition.addToken(name="Input.rte.mc.dy_sample", datatype=float, optional=True) ], parents=['uvspec'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True, ) mc_spherical = option_definition.option( name='mc_spherical', group='geometry', helpstr='Use MYSTIC spherical geometry.', documentation=documentation['mc_spherical'], tokens=[ option_definition.addLogical(name='id', logicals=['1D', '3D'], setting='DIM_'), option_definition.addSetting(name='Input.rte.mc.spherical[id]', setting=1) ], gui_inputs=(GUI_definition.ListInput(name='dimension', valid_range=['1d']), ), parents='mc_backward', childs=['mc_refraction'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), mystic=True, #showInGui=False, ) mc_spherical3D_scene = option_definition.option( name='mc_spherical3D_scene', group='geometry', helpstr='Define scene on globe.', documentation=documentation['mc_spherical3D_scene'], tokens=[ option_definition.addSetting( name='Input.rte.mc.spherical3D_scene', setting=1), option_definition.addToken( name='Input.rte.mc.spherical3D_scene_lon_min', datatype=float, gui_name='LON_W'), option_definition.addToken( name='Input.rte.mc.spherical3D_scene_lon_max', datatype=float, gui_name='LON_E'), option_definition.addToken( name='Input.rte.mc.spherical3D_scene_lat_min', datatype=float, gui_name='LAT_S'), option_definition.addToken( name='Input.rte.mc.spherical3D_scene_lat_max', datatype=float, gui_name='LAT_N') ], speaker='mc_spherical', enable_values=("3d", ), islidar=True, showInGui=False, ) mc_satellite_view = option_definition.option( name='mc_satellite_view', group='geometry', helpstr='Simulate a satellite image.', documentation=documentation['mc_satellite_view'], tokens=[ option_definition.addSetting( name='Input.rte.mc.pan_angles', setting='calloc (4, sizeof(double))'), option_definition.addToken(name='Input.rte.mc.pan_angles[0]', datatype=float), option_definition.addToken(name='Input.rte.mc.pan_angles[1]', datatype=float), option_definition.addToken(name='Input.rte.mc.pan_angles[2]', datatype=float), option_definition.addToken(name='Input.rte.mc.pan_angles[3]', datatype=float), option_definition.addSetting(name='Input.rte.mc.panorama', setting='PAN_MODE_SATELLITE'), option_definition.addSetting( name='Input.rte.mc.allocate_umu_and_phi', setting=True) ], parents=['mc_backward'], non_parents=['mc_panorama_view'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True, islidar=True, showInGui=False, ) mc_satellite_position = option_definition.option( name='mc_satellite_position', group='geometry', helpstr='Define the position of the satellite.', documentation=documentation['mc_satellite_position'], tokens=[ option_definition.addSetting( name='Input.rte.mc.sensorposition', setting='MC_SENSORPOSITION_SPHERICAL'), option_definition.addToken( name='Input.rte.mc.sensorposition_lon', datatype=float), option_definition.addToken( name='Input.rte.mc.sensorposition_lat', datatype=float), option_definition.addToken( name='Input.rte.mc.sensorposition_alt', datatype=float) ], non_parents=['mc_sensor_position'], islidar=True, showInGui=False, ) mc_sun_position = option_definition.option( name='mc_sun_position', group='geometry', helpstr='Sun position', documentation=documentation['mc_sun_position'], tokens=[ option_definition.addSetting(name='Input.atm.sza_source', setting='SZA_DIRECT_INPUT'), option_definition.addToken(name='Input.atm.phi0_spher', datatype=float), option_definition.addToken(name='Input.atm.sza_spher', datatype=float) ], islidar=True, speaker='mc_sperical', enable_values=('3D', ), showInGui=False, ) mc_sensordirection = option_definition.option( name='mc_sensordirection', group='geometry', helpstr='Define viewing direction of an irradiance sensor.', documentation=documentation['mc_sensordirection'], tokens=[ option_definition.addToken( name="Input.rte.mc.sensordirection_dx", datatype=float, gui_name='dx'), option_definition.addToken( name="Input.rte.mc.sensordirection_dy", datatype=float, gui_name='dy'), option_definition.addToken( name="Input.rte.mc.sensordirection_dz", datatype=float, gui_name='dz'), option_definition.addSetting( name="Input.rte.mc.sensordirection", setting=1) ], parents=['mc_backward'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), mystic=True, ) mc_sensorposition = option_definition.option( name='mc_sensorposition', group='geometry', helpstr='Define the position of a sensor.', documentation=documentation['mc_sensorposition'], tokens=[ option_definition.addToken( name="Input.rte.mc.sensorposition_x", datatype=float, gui_name='x'), option_definition.addToken( name="Input.rte.mc.sensorposition_y", datatype=float, gui_name='y'), option_definition.addToken( name="Input.rte.mc.sensorposition_z", datatype=float, gui_name='z'), option_definition.addSetting( name="Input.rte.mc.sensorposition", setting='MC_SENSORPOSITION_CARTESIAN') ], parents=['mc_backward'], non_parents=['mc_satellite_position'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True, ) mc_reference_to_nn = option_definition.option( name='mc_reference_to_nn', group='geometry', helpstr='The sampled pixels correspond to he surface pixels.', documentation=documentation['mc_reference_to_nn'], tokens=[ option_definition.addSetting( name='Input.rte.mc.reference_to_NN', setting=1, default=0) ], parents=['mc_backward'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True) mc_panorama_forward = option_definition.option( name='mc_panorama_forward', group='geometry', helpstr='Simulate a 4pi panorama with forward MYSTIC.', documentation=documentation['mc_panorama_forward'], tokens=[ option_definition.addSetting( name='Input.rte.mc.pan_angles', setting='calloc (4, sizeof(double))'), option_definition.addSetting(name='Input.rte.mc.pan_angles[0]', setting=0.0), option_definition.addSetting(name='Input.rte.mc.pan_angles[1]', setting=360.0), option_definition.addSetting(name='Input.rte.mc.pan_angles[2]', setting=0.0), option_definition.addSetting(name='Input.rte.mc.pan_angles[3]', setting=180.0), option_definition.addSetting( name='Input.rte.mc.panorama_forward', setting=1), option_definition.addSetting( name='Input.rte.mc.allocate_umu_and_phi', setting=True) ], non_parents=['mc_satellite_view', 'mc_backward', 'mc_escape'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True) mc_panorama_view = option_definition.option( name='mc_panorama_view', group='geometry', helpstr='Simulate a panorama.', documentation=documentation['mc_panorama_view'], tokens=[ option_definition.addSetting( name='Input.rte.mc.pan_angles', setting='calloc (4, sizeof(double))'), option_definition.addToken(name='Input.rte.mc.pan_angles[0]', datatype=float), option_definition.addToken(name='Input.rte.mc.pan_angles[1]', datatype=float), option_definition.addToken(name='Input.rte.mc.pan_angles[2]', datatype=float), option_definition.addToken(name='Input.rte.mc.pan_angles[3]', datatype=float), option_definition.addSetting(name='Input.rte.mc.panorama', setting='PAN_MODE_CAMERA'), option_definition.addSetting( name='Input.rte.mc.allocate_umu_and_phi', setting=True) ], parents=['mc_backward'], non_parents=['mc_satellite_view'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True, childs=['mc_panorama_alignment', 'mc_panorama']) mc_panorama_alignment = option_definition.option( name='mc_panorama_alignment', group='geometry', helpstr='Panorama alignment.', documentation=documentation['mc_panorama_alignment'], tokens=option_definition.addLogical( name='Input.rte.mc.pan_alignment', logicals=['mu', 'sun', 'zenith'], setting='PAN_ALIGNMENT_'), threedmystic=True, parents=['mc_panorama_view'], ) mc_panorama = option_definition.option( name='mc_panorama', group='geometry', helpstr='Panorama settings.', documentation=documentation['mc_panorama'], tokens=[ option_definition.addLogical(name='id', logicals=[ 'distr_photons_over_pixel', 'no_pixel', 'quicklook', 'with_direct_rad', 'weight_with_cos', 'circumsolar_var_red' ], setting='PAN_FLAG_'), option_definition.addSetting(name='Input.rte.mc.pan[id]', setting=1) ], parents=['mc_panorama_view'], threedmystic=True, non_unique=True, ) mc_blitz_position = option_definition.option( name='mc_blitz_position', group='geometry', helpstr='Define lightning as source.', documentation=documentation['mc_blitz_position'], tokens=[ option_definition.addSetting( name='Input.rte.mc.blitz_position', setting='calloc (6, sizeof(double))'), option_definition.addToken( name='Input.rte.mc.blitz_position[0]', datatype=float), option_definition.addToken( name='Input.rte.mc.blitz_position[1]', datatype=float), option_definition.addToken( name='Input.rte.mc.blitz_position[2]', datatype=float), option_definition.addToken( name='Input.rte.mc.blitz_position[3]', datatype=float), option_definition.addToken( name='Input.rte.mc.blitz_position[4]', datatype=float), option_definition.addToken( name='Input.rte.mc.blitz_position[5]', datatype=float), option_definition.addSetting(name='Input.source', setting='SRC_BLITZ'), option_definition.addSetting( name='Input.rte.mc.allocate_umu_and_phi', setting=True) ], parents=['mc_forward'], speaker='rte_solver', enable_values=("mystic", "montecarlo"), threedmystic=True, showInGui=False, ) self.options = [ sza, sza_file, phi0, phi, umu, mc_bw_umu_file, earth_radius, latitude, longitude, # missing time, day_of_year, mc_bcond, mc_sample_grid, mc_spherical, mc_spherical3D_scene, mc_satellite_view, mc_satellite_position, mc_sun_position, mc_sensordirection, mc_sensorposition, mc_reference_to_nn, mc_panorama_view, mc_panorama_alignment, mc_panorama, mc_panorama_forward, mc_blitz_position, ]
def __init__(self): documentation = get_molecular_documentation() atmosphere_file = option_definition.option( name='atmosphere_file', group='atmosphere', helpstr='Location of the atmosphere data file.', documentation=documentation['atmosphere_file'], tokens= option_definition.addToken(name='Input.atmosphere_filename', datatype=str, valid_range=['subarctic_winter', 'subarctic_summer', 'midlatitude_summer', 'midlatitude_winter', 'tropics', 'US-standard', io.IOBase]), parents=['uvspec'], plot = {'plot_type': '2D', 'optional_args': {'column_names': ( "altitude", "pressure", "temperature", "air", "ozone", "oxygen", "water vapour", "CO2", "NO2",) } }, mandatory=True, ) atmosphere_file_3D = option_definition.option( name='atmosphere_file_3D', group='atmosphere', helpstr='Location of the 3D atmosphere data file.', documentation=documentation['atmosphere_file_3D'], tokens= [option_definition.addToken(name='Input.atmosphere3d_filename', datatype=str), option_definition.addSetting(name='Input.atmosphere3d', setting='True'), option_definition.addSetting(name='isp', setting='get_caoth_index(&Input.caoth,&Input.n_caoth,"molecular_3d",0)'), option_definition.addSetting(name='Input.caoth[isp].source', setting='CAOTH_FROM_3D'), option_definition.addSetting(name='Input.caoth[isp].filename', setting='"profile_mol3d_dummy.dat"'), option_definition.addSetting(name='Input.caoth[isp].properties', setting='PROP_HU')], parents=['uvspec'], showInGui = False, developer = False, threedmystic =True ) radiosonde = option_definition.not_yet_lex2py_option( name='radiosonde', group='atmosphere', helpstr='Specify density profiles.', documentation=documentation['radiosonde'], gui_inputs=(GUI_definition.TextInput(name=''),), parents=['uvspec'], ) radiosonde_levels_only = option_definition.option( name='radiosonde_levels_only', group='atmosphere', helpstr='', documentation=documentation['radiosonde_levels_only'], tokens=option_definition.addSetting(name='Input.atm.rs_add_upper_levels',setting='FALSE'), parents=['uvspec'], ) mol_file = option_definition.option( name='mol_file', group='molecular', documentation=documentation['mol_file'], gui_inputs=(GUI_definition.ListInput(name='mol_id', valid_range=['O3', 'O2', 'H2O', 'CO2', 'NO2', 'BRO', 'OCLO', 'HCHO', 'O4', 'SO2', 'CH4', 'N2O', 'CO', 'N2'], optional=False), GUI_definition.FileInput(name='Input.atm.filename[mol_id]'), GUI_definition.ListInput(name='Input.atm.unit_profile[mol_id]', valid_range=['','cm_3', 'm_3', 'MMR', 'VMR', 'RH'], optional=True),), tokens = [option_definition.addLogical(name='mol_id', logicals=['O3', 'O2', 'H2O', 'CO2', 'NO2', 'BRO', 'OCLO', 'HCHO', 'O4', 'SO2', 'CH4', 'N2O', 'CO', 'N2'], setting='MOL_' ) , option_definition.addToken(name='Input.atm.filename[mol_id]', datatype=io.IOBase), option_definition.addLogical(name='Input.atm.unit_profile[mol_id]', logicals=['cm_3', 'm_3', 'MMR', 'VMR', 'RH'], optional=True)], parents=['uvspec'], non_unique=True, ) pressure = option_definition.option( name='pressure', group='atmosphere', helpstr='Surface pressure', documentation=documentation['pressure'], gui_inputs=(GUI_definition.FloatInput(name='Input.pressure', default='NOT_DEFINED_FLOAT', valid_range=[0, 1000000.0]),), tokens=option_definition.addToken(name='Input.pressure', datatype=float, default='NOT_DEFINED_FLOAT', valid_range=[0,1e6]), parents=['uvspec'], ) refractive_index_file = option_definition.option( name='refractive_index_file', group='atmosphere', helpstr='', documentation=documentation['refractive_index_file'], gui_inputs=(GUI_definition.TextInput(name='Input.filename[FN_REFIND]'),), tokens=option_definition.addToken(name='Input.filename[FN_REFIND]', datatype=str), parents=['uvspec'], ) crs_model = option_definition.option( name='crs_model', group='molecular', helpstr='Specify cross section.', documentation=documentation['crs_model'], gui_inputs=(GUI_definition.ListInput(name='mol_id', valid_range=['no2', 'o3', 'o4', 'rayleigh'], optional=False), GUI_definition.ListInput(name='crs_model', valid_range=['Bass_and_Paur', 'Molina', 'Daumont', 'Serdyuchenko', 'Bogumil', 'Bodhaine', 'Bodhaine29', 'Nicolet', 'Penndorf', 'Burrows', 'Vandaele', 'Greenblatt', 'Thalman'], optional=False),), tokens= [option_definition.addLogical(name='mol_id', logicals=['no2', 'o3', 'o4', 'rayleigh'], setting='CRS_MOL_'), option_definition.addLogical(name='Input.crs_model[mol_id]', logicals=[ 'Bodhaine', 'Nicolet', 'Penndorf', 'Bodhaine29', 'Bass_and_Paur', 'Molina', 'Daumont', 'Serdyuchenko', 'Bogumil', 'Burrows', 'Vandaele', 'Greenblatt', 'Thalman'], setting='CRS_MODEL_')], parents=['uvspec'], non_unique=True, ) crs_file = option_definition.option( name='crs_file', group='molecular', documentation=documentation['crs_file'], gui_inputs=(GUI_definition.ListInput(name='mol_id', valid_range=['O3', 'O2', 'H2O', 'CO2', 'NO2', 'BRO', 'OCLO', 'HCHO', 'O4', 'SO2', 'CH4', 'N2O', 'CO', 'N2'], optional=False), GUI_definition.FileInput(name='Output.crs.filename[mol_id]'),), tokens = [option_definition.addLogical(name='mol_id', logicals=['O3', 'O2', 'H2O', 'CO2', 'NO2', 'BRO', 'OCLO', 'HCHO', 'O4', 'SO2', 'CH4', 'N2O', 'CO', 'N2'], setting='MOL_' ) , option_definition.addToken(name='Output.crs.filename[mol_id]', datatype=io.IOBase)], parents=['uvspec'], non_unique=True, ) rayleigh_depol = option_definition.option( name='rayleigh_depol', group='atmosphere', helpstr='Rayleigh depolarization factor.', documentation=documentation['rayleigh_depol'], gui_inputs=(GUI_definition.FloatInput(name='Input.rayleigh_depol'),), tokens=option_definition.addToken(name='Input.rayleigh_depol', datatype=float, default='NOT_DEFINED_FLOAT'), parents=['uvspec'], ) mol_abs_param = option_definition.option( name='mol_abs_param', group='spectral', helpstr='Set correlated_k scheme. ', documentation=documentation['mol_abs_param'], tokens = [option_definition.addLogical(name='Input.ck_scheme', logicals=['kato', 'kato2', 'kato2.96','kato2andwandji','fu','avhrr_kratz','sbdart','lowtran','reptran','reptran_channel','crs',io.IOBase], setting='CK_'), option_definition.addToken(name='Input.ck_reptran_arg', datatype=str, optional=True)], parents=['uvspec'], childs= ['ck_lowtran_absorption','ck_fu_h2o_continuum'], continious_update=True, ) reptran_file = option_definition.option( name='reptran_file', group='spectral', helpstr='File containing representative wavelengths.', documentation=documentation['reptran_file'], tokens=option_definition.addToken(name='Input.filename[FN_REPTRAN]', datatype=io.IOBase), parents=['uvspec'], showInGui = False, ) ck_lowtran_absorption = option_definition.option( name='ck_lowtran_absorption', group='molecular', helpstr='Switch off absorption by individual minor trace gases.', documentation=documentation['ck_lowtran_absorption'], gui_inputs=(GUI_definition.ListInput(name='Input.absorption_gas', valid_range=['O4', 'N2', 'CO', 'SO2', 'NH3', 'NO', 'HNO3']), GUI_definition.ListInput(name='On/Off',valid_range=['on','off'], default='On'),), tokens = [option_definition.addLogical(name='mol_id', logicals=['O4','N2','CO','SO2','NH3','NO','HNO3'], setting='CK_ABS_' ) , option_definition.addLogical(name='Input.ck_abs[mol_id]', logicals=['on','off'], setting='SWITCH_')], parents=['mol_abs_param'], speaker="mol_abs_param", enable_values=("lowtran",), non_unique=True, ) ck_fu_h2o_continuum = option_definition.option( name='ck_fu_h2o_continuum', group='molecular', helpstr='', #TODO documentation=documentation['ck_fu_h2o_continuum'], tokens=option_definition.addLogical(name='Input.ck_h2ocont',logicals=['on','off','v2.1','v2.4'],setting='CK_H2OCONT_'), parents=['uvspec'], speaker='mol_abs_param', enable_values=('fu',), #TODO:stimmt das? developer=True, ) mol_tau_file = option_definition.option( name='mol_tau_file', group='molecular', helpstr='Location of Molecular optical depth file.', documentation=documentation['mol_tau_file'], gui_inputs=(GUI_definition.ListInput(name='id', valid_range=['sca', 'abs'], optional=False), GUI_definition.FileInput(name='Input.filename[id]'),), tokens = [option_definition.addLogical(name='id', logicals=[ 'sca','abs'], setting='FN_MOL_TAU_'), option_definition.addToken(name='Input.filename[id]', datatype=io.IOBase)], parents=['uvspec'], non_unique=True, ) mol_modify = option_definition.option( name='mol_modify', group='molecular', helpstr='Modify column of molecular specie', documentation=documentation['mol_modify'], gui_inputs = ( GUI_definition.ListInput(name='moltype', valid_range=[ 'O3','O2','H2O','CO2','NO2','BRO','OCLO','HCHO','O4','SO2','CH4','N2O','CO','N2'], optional=False), GUI_definition.FloatInput(name='value', valid_range=[0, 1000000.0]), GUI_definition.ListInput(name='unit', valid_range=[ 'DU', 'CM_2', 'MM'], optional=False)), tokens = [option_definition.addLogical(name='id', logicals=[ 'O3','O2','H2O','CO2','NO2','BRO','OCLO','HCHO','O4','SO2','CH4','N2O','CO','N2'], setting='MOL_'), option_definition.addToken(name='Input.atm.column[id]', datatype=float), option_definition.addLogical(name='Input.atm.unit_column[id]', logicals=[ 'DU', 'CM_2', 'MM'], setting='MOL_UNIT_')], parents=['uvspec'], non_unique=True, ) mixing_ratio = option_definition.option( name='mixing_ratio', group='molecular', helpstr='Mixing ratio of molecular specie', documentation=documentation['mixing_ratio'], gui_inputs = (GUI_definition.ListInput(name='moltype', valid_range=[ 'O2','H2O','CO2','NO2','CH4','N2O','F11','F12','F22'], optional=False), GUI_definition.FloatInput(name='value', valid_range=[0, 1000000.0])), tokens = [option_definition.addLogical(name='id', logicals=[ 'O2','H2O','CO2','NO2','CH4','N2O','F11','F12','F22'], setting='MX_'), option_definition.addToken(name='Input.mixing_ratio[id]', datatype=float, valid_range=[0,1e6])], parents=['uvspec'], non_unique=True, ) self.options = [atmosphere_file, atmosphere_file_3D, radiosonde, radiosonde_levels_only, mol_file, mixing_ratio, mol_modify, pressure, refractive_index_file, crs_model, crs_file, rayleigh_depol, mol_abs_param, ck_lowtran_absorption, ck_fu_h2o_continuum, mol_tau_file, reptran_file, ]
def __init__(self): documentation = get_spectral_documentation() wavelength = option_definition.option( name='wavelength', group='spectral', helpstr= 'Set the wavelength range by specifying first and last wavelength in nm.', documentation=documentation['wavelength'], gui_inputs=( GUI_definition.FloatInput(name='Input.wl.start', default=None, valid_range=[0, 1000000.0]), GUI_definition.FloatInput(name='Input.wl.end', default=None, valid_range=[0, 1000000.0], optional=True), ), tokens=[ option_definition.addToken(name='Input.wl.start', datatype=float, default='NOT_DEFINED_FLOAT', valid_range=[0, 1e6]), option_definition.addToken(name='Input.wl.end', datatype=float, default='NOT_DEFINED_FLOAT', valid_range=[0, 1e6], optional=True) ], #TODO:argument 2 should be bigger that argument 1 parents=['uvspec'], non_parents=['wavelength_index'], ) wavelength_step = option_definition.option( name='wavelength_step', group='spectral', helpstr= 'Set the wavelength step (in nm) in conjunction with the wavelength range.', documentation=['wavelength_step'], gui_inputs=(), tokens=[], parents=['uvspec'], non_parents=['wavelength_index'], ) wavelength_index = option_definition.option( name='wavelength_index', group='spectral', helpstr='Set the wavelengths to be selected.', documentation=documentation['wavelength_index'], gui_inputs=( GUI_definition.IntegerInput(name='Input.wl.start_index'), GUI_definition.IntegerInput(name='Input.wl.end_index', optional=True), ), tokens=[ option_definition.addToken( name='Input.wl.start_index', datatype=int, default='NOT_DEFINED_INTEGER', ), option_definition.addToken(name='Input.wl.end_index', datatype=int, default='NOT_DEFINED_INTEGER', optional=True) ], parents=['uvspec'], non_parents=['wavelength'], ) wavelength_grid_file = option_definition.option( name='wavelength_grid_file', group='spectral', helpstr= 'Location of file with wavelength grid used for the internal transmittance calculations.', documentation=documentation['wavelength_grid_file'], gui_inputs=(GUI_definition.FileInput( name='Input.filename[FN_WLTRANS]'), ), tokens=option_definition.addToken( name='Input.filename[FN_WLTRANS]', datatype=io.IOBase), parents=['uvspec'], non_parents=['thermal_bands_file'], ) thermal_bands_file = option_definition.option( name='thermal_bands_file', group='spectral', helpstr= 'File with the center wavelengths and the wavelength band intervals for calculations in the thermal range.', documentation=documentation['thermal_bands_file'], gui_inputs=(GUI_definition.FileInput( name='Input.filename[FN_WLBANDS]'), ), tokens=option_definition.addToken( name='Input.filename[FN_WLBANDS]', datatype=io.IOBase), parents=['uvspec'], non_parents=['filter_function_file', 'slit_function_file'], ) thermal_bandwidth = option_definition.option( name='thermal_bandwidth', group='spectral', documentation=documentation['thermal_bandwidth'], gui_inputs=( GUI_definition.FloatInput(name='Input.bandwidth', valid_range=[0, 1000000.0]), GUI_definition.ListInput(name='Input.bandwidth_unit', valid_range=['', 'nm', 'cm-1'], optional=True), ), tokens=[ option_definition.addToken(name='Input.bandwidth', datatype=float, valid_range=[0, 1e6]), option_definition.addLogical(name='Input.bandwidth_unit', logicals=['nm', 'cm-1'], setting='UNIT_PER_', optional=True) ], parents=['uvspec'], ) source = option_definition.option( name='source', group='spectral', helpstr='Source of radiation.', documentation=documentation['source'], gui_inputs=( GUI_definition.ListInput(name='Input.source', valid_range=['thermal', 'solar']), GUI_definition.FileInput( name='Input.filename[FN_EXTRATERRESTRIAL]', optional=True), GUI_definition.ListInput( name='Input.spectrum_unit', valid_range=['', 'per_nm', 'per_cm-1', 'per_band'], optional=True), ), tokens=[ option_definition.addLogical(name='Input.source', logicals=['thermal', 'solar'], setting='SRC_'), option_definition.addToken( name='Input.filename[FN_EXTRATERRESTRIAL]', datatype=io.IOBase, optional=True), option_definition.addLogical( name='Input.spectrum_unit', logicals=['per_nm', 'per_cm-1', 'per_band'], setting='UNIT_', optional=True) ], parents=['uvspec'], plot={ 'plot_type': '2D', 'optional_args': { 'column_names': ( "wavelength", "extraterrestrial flux", ) } }) mc_sun_angular_size = option_definition.option( name='mc_sun_angular_size', group='spectral', documentation=documentation['mc_sun_angular_size'], tokens=option_definition.addToken(name='Input.rte.mc.sun_radius', datatype=float), threedmystic=True, showInGui=False, ) mc_lidar = option_definition.option( name='mc_lidar', group='spectral', helpstr='Use local estimator to simulate a lidar.', documentation=documentation['mc_lidar'], tokens=[ option_definition.addSetting(name='Input.source', setting='SRC_LIDAR'), option_definition.addSetting(name='Input.rte.mc.escape', setting=0), option_definition.addSetting(name='Input.rte.mc.locest', setting='MCLIDAR_SPACE'), option_definition.addLogical(name='Input.rte.mc.locest', logicals=[ 'ascope', 'polarize', 'space', 'falcon', 'simple', 'pilot', 'moon', 'test' ], setting='MCLIDAR_', optional=True) ], parents=['uvspec'], non_parents=['source'], showInGui=False, islidar=True) mc_lidar_file = option_definition.option( name='mc_lidar_file', group='spectral', helpstr= 'File containing positions, looking directions, and opening angles of lasers and detectors for lidar simulations in MYSTIC.', documentation=documentation['mc_lidar_file'], tokens=option_definition.addToken( name='Input.rte.mc.filename[FN_MC_LIDAR]', datatype=io.IOBase), parents=['uvspec'], non_parents=['source'], showInGui=False, islidar=True) mc_radar = option_definition.option( name='mc_radar', group='spectral', helpstr='Switch on radar.', documentation=documentation['mc_radar'], tokens=[ option_definition.addSetting(name='Input.source', setting='SRC_LIDAR'), option_definition.addSetting(name='Input.rte.mc.escape', setting=0), option_definition.addSetting(name='Input.rte.mc.locest', setting='MCRADAR') ], parents=['uvspec'], non_parents=['source'], showInGui=False, islidar=True) self.options = [ wavelength, wavelength_index, wavelength_grid_file, thermal_bands_file, thermal_bandwidth, source, mc_lidar, mc_lidar_file, mc_radar, mc_sun_angular_size, ]
def __init__(self): documentation = get_cloud_documentation() #uvspec function to initialize new profile wc_file = option_definition.option( #TODO: option 3D only ifthreedmystic name='wc_file', group='cloud', helpstr='Location of file defining water cloud properties.', documentation=documentation['wc_file'], tokens = [option_definition.addSetting(name='isp', setting=option_definition.CaothType('wc')), option_definition.addLogical(name='Input.caoth[isp].source', logicals=option_definition.ProfileType().get_valid_range(), setting='CAOTH_FROM_'), option_definition.addToken(name='Input.caoth[isp].filename', datatype=io.IOBase)], parents=['uvspec'], childs=['wc_modify',\ 'interpret_as_level',\ 'wc_properties',\ 'cloudcover'], plot = {'plot_type': '2D', 'optional_args': {'column_names': ( "altitude", "liquid water content", "effective radius",) } } ) wc_properties = option_definition.option( name='wc_properties', group='cloud', helpstr= 'Define how liquid water content and effective droplet radius are translated to optical properties. ', documentation=documentation['wc_properties'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('wc')), option_definition.addLogical( name='Input.caoth[isp].properties', logicals=['hu', 'echam4', 'mie', io.IOBase], setting='PROP_', gui_name='properties'), option_definition.addLogical( name='Input.caoth[isp].interpolate', logicals=['interpolate'], optional=True, gui_name='interpolate') ], parents=['wc_file'], ) wc_modify = option_definition.option( #TODO: valid_ranges for GUI!! name='wc_modify', group='cloud', helpstr='Modify water cloud optical properties.', documentation=documentation['wc_modify'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('wc')), option_definition.addLogical( name='id1', logicals=['gg', 'ssa', 'tau', 'tau550'], setting='MODIFY_VAR_', gui_name='variable'), option_definition.addLogical(name='id2', logicals=['set', 'scale'], setting='MODIFY_TYPE_', gui_name='scale/set'), option_definition.addToken( name='Input.caoth[isp].modify[id1][id2]', datatype=float, gui_name='value') ], parents=['wc_file'], non_unique=True, ) ic_file = option_definition.option( #TODO: option 3D only ifthreedmystic name='ic_file', group='cloud', helpstr='Location of file defining ice cloud properties.', documentation=documentation['ic_file'], tokens = [option_definition.addSetting(name='isp', setting=option_definition.CaothType('ic')), option_definition.addLogical(name='Input.caoth[isp].source', logicals=option_definition.ProfileType().get_valid_range(), setting='CAOTH_FROM_'), option_definition.addToken(name='Input.caoth[isp].filename', datatype=io.IOBase)], parents=['uvspec'], childs=['ic_modify','ic_habit',\ 'ic_fu', 'interpret_as_level',\ 'ic_properties',\ 'cloudcover'], plot = {'plot_type': '2D', 'optional_args': {'column_names': ( "altitude", "ice water content", "effective radius",) } } ) ic_properties = option_definition.option( # TODO: raytracing should only be enabled ifthreedmystic, see also ic_raytracing_file name='ic_properties', group='cloud', helpstr= 'Define how ice water content and effective droplet radius are translated to optical properties. ', documentation=documentation['ic_properties'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('ic')), option_definition.addLogical( name='Input.caoth[isp].properties', logicals=[ 'fu', 'echam4', 'yang', 'key', 'baum', 'baum_v36', 'hey', 'yang2013', 'raytracing', io.IOBase ], setting='PROP_', gui_name='properties'), option_definition.addLogical( name='Input.caoth[isp].interpolate', logicals=['interpolate'], optional=True, gui_name='interpolate') ], parents=['ic_file'], childs=['ic_habit', 'ic_habit_yang2013'], continious_update=True, ) ic_modify = option_definition.option( #TODO: valid_ranges for GUI!! name='ic_modify', group='cloud', helpstr='Modify ice cloud optical properties.', documentation=documentation['ic_modify'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('ic')), option_definition.addLogical( name='id1', logicals=['gg', 'ssa', 'tau', 'tau550'], setting='MODIFY_VAR_', gui_name='variable'), option_definition.addLogical(name='id2', logicals=['set', 'scale'], setting='MODIFY_TYPE_', gui_name='scale/set'), option_definition.addToken( name='Input.caoth[isp].modify[id1][id2]', datatype=float, gui_name='value') ], parents=['ic_file'], non_unique=True, ) ic_habit = option_definition.option( name='ic_habit', group='cloud', helpstr= 'Ice crystal habit for the \citet{Yang2000}, \citet{Key2002}, \code{baum_v36}, \code{hey} parameterizations.', documentation=documentation['ic_habit'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('ic')), option_definition.addLogical( name='Input.caoth[isp].habit', logicals=[ 'solid-column', 'hollow-column', 'rough-aggregate', 'rosette-4', 'rosette-6', 'plate', 'droxtal', 'dendrite', 'ghm' ], setting='IC_HABIT_') ], parents=['ic_file'], speaker='ic_properties', enable_values=('key', 'yang', 'hey', 'baum_v36'), ) ic_habit_yang2013 = option_definition.option( name='ic_habit_yang2013', group='cloud', helpstr= 'Ice crystal habit for the \citet{yang2013} parameterization.', documentation=documentation['ic_habit_yang2013'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('ic')), option_definition.addLogical( name='Input.caoth[isp].habit', logicals=[ 'column_8elements', 'droxtal', 'hollow_bullet_rosette', 'hollow_column', 'plate', 'plate_10elements', 'plate_5elements', 'solid_bullet_rosette', 'solid_column' ], setting='IC_HABIT_'), option_definition.addLogical( name='Input.caoth[isp].roughness', logicals=['smooth', 'moderate', 'severe'], setting='IC_ROUGHNESS_') ], parents=['ic_file'], speaker='ic_properties', enable_values=('yang2013', ), ) ic_fu = option_definition.option( name='ic_fu', group='cloud', documentation=documentation['ic_fu'], tokens=[ option_definition.addSetting( name='isp', setting=option_definition.CaothType('ic')), option_definition.addLogical( name='id1', logicals=['reff_def', 'deltascaling'], setting='IC_FU_'), option_definition.addLogical(name='id2', logicals=['on', 'off'], setting='SWITCH_'), option_definition.addSetting( name='Input.caoth[isp].ic_fu[id1]', setting='id2') ], parents=['ic_file'], non_unique=True, ) ic_raytracing_file = option_definition.option( # TODO: should only be enabled ifthreedmystic, but only if the same is true for ic_properties raytracing name='ic_raytracing_file', group='cloud', documentation=documentation['ic_raytracing_file'], tokens=[ option_definition.addToken( name='Input.filename[FN_RAYTRACING]', datatype=io.IOBase), ], ) cloud_fraction_file = option_definition.option( name='cloud_fraction_file', group='cloud', documentation=documentation['cloud_fraction_file'], tokens=[ option_definition.addToken( name='Input.filename[FN_CLOUD_FRACTION]', datatype=io.IOBase), ], ) cloud_overlap = option_definition.option( name='cloud_overlap', group='cloud', documentation=documentation['cloud_overlap'], tokens=[ option_definition.addLogical( name='Input.cloud_overlap', logicals=['rand', 'max', 'maxrand', 'off'], setting='CLOUD_OVERLAP_') ], ) cloudcover = option_definition.option( name='cloudcover', group='cloud', helpstr= 'Fraction of the horizontal sky area which is covered by clouds.', documentation=documentation['cloudcover'], tokens=[ option_definition.addToken( name='isp', datatype=option_definition.CaothType, valid_range=['wc', 'ic']), option_definition.addToken(name='Input.caoth[isp].cloudcover', datatype=float, valid_range=[0, 1]), option_definition.addSetting(name='Input.caoth[isp].ipa', setting=1), option_definition.addSetting(name='Input.ipa', setting=1, default=0) ], parents=['ic_file', 'wc_file'], non_unique=True, ) self.options = [ wc_file, wc_properties, wc_modify, ic_file, ic_properties, ic_modify, ic_habit, ic_habit_yang2013, ic_fu, ic_raytracing_file, cloud_fraction_file, cloud_overlap, cloudcover ]
def __init__(self): documentation = get_solver_documentation() rte_solver = option_definition.option( name='rte_solver', group='solver', helpstr='Radiative transfer equation solver.', documentation=documentation['rte_solver'], gui_inputs=(GUI_definition.ListInput(name='solver', valid_range=[ 'disort', 'twostr', 'mystic', 'rodents', 'sslidar', 'null' ], optional=False), ), tokens=option_definition.addLogical( name='Input.rte.solver', logicals=[ 'disort', 'twostr', 'mystic', 'rodents', 'sslidar', 'null', 'sdisort', 'spsdisort', 'fdisort1', 'fdisort2', 'sos', 'polradtran', 'ftwostr', 'montecarlo', 'tzs', 'sssi', 'sss', 'twostrebe', 'twomaxrnd', 'twomaxrnd3C' ], setting='SOLVER_'), parents=['uvspec'], childs=[ 'polradtran_quad_type', 'polradtran', 'polradtran_max_delta_tau', 'pseudospherical', 'disort_spherical_albedo', 'disort_intcor', 'isotropic_source_toa', 'raman', 'number_of_streams', 'deltam', 'nrefrac', 'brdf_cam', 'brdf_cam_solar_wind', # Mystic options are not enabled unless solver is mystic of monte carlo, see mc_options.py 'mc_escape', 'mc_vroom', 'mc_backward', 'mc_spectral_is', 'mc_spectral_is_wvl', 'mc_forward_output', 'mc_albedo_file', 'mc_albedo_spectral_file', 'mc_albedo_type', 'mc_rossli_file', 'mc_backward_output', 'mc_backward_writeallpixels', 'mc_basename', 'mc_delta_scaling', 'mc_elevation_file', 'mc_tenstream', 'mc_ipa', 'mc_tipa', 'ipa_3d', 'tipa', 'mc_maxscatters', 'mc_minscatters', 'mc_minphotons', 'mc_photons', 'mc_photons_file', 'mc_polarisation', 'mc_wcloud_file', 'mc_icloud_file', 'mc_randomseed', 'mc_rpv_file', 'mc_rpv_spectral_file', 'mc_rpv_type', 'mc_ambrals_spectral_file', 'mc_ambrals_type', 'mc_spherical', 'mc_std', 'sur_temperature_file', 'mc_sample_grid', 'mc_sensordirection', 'mc_sensorposition', 'mc_reference_to_nn', 'mc_bw_umu_file', 'mc_truncate', 'mc_bcond', 'mc_coherent_backscatter', 'mc_surface_reflectalways', 'mc_refraction', 'mc_visualize', 'mc_hiddenline', 'mc_surfaceparallel', 'mc_jacobian', 'mc_jacobian_std', 'sslidar', 'sslidar_nranges', 'sslidar_polarisation', 'tzs_cloud_top_height', 'twomaxrnd3C_scale_cf', 'mc_nca' # CK2019 added nca ], continious_update=True, ) pseudospherical = option_definition.option( name='pseudospherical', group='solver', helpstr= 'Invokes pseudospherical geometry for disort/twostr solver.', documentation=documentation['pseudospherical'], tokens=option_definition.addSetting( name='Input.rte.pseudospherical', setting=1), parents=['rte_solver'], speaker='rte_solver', enable_values=( "disort", "twostr", )) disort_spherical_albedo = option_definition.option( name='disort_spherical_albedo', group='solver', helpstr='Calculate spherical albedo.', documentation=documentation['disort_spherical_albedo'], tokens=[ option_definition.addSetting(name='Input.rte.ibcnd', setting=1), option_definition.addSetting(name='Input.rte.nphi', setting=0) ], parents=['rte_solver'], speaker='rte_solver', enable_values=("disort", ), developer=True) disort_intcor = option_definition.option( name='disort_intcor', group='solver', helpstr='Intensity correction method', documentation=documentation['disort_intcor'], gui_inputs=(GUI_definition.ListInput( name='disort_intcor', valid_range=['phase', 'moments', 'off']), ), tokens=option_definition.addLogical( name="Input.rte.disort_icm", logicals=['phase', 'moments', 'off'], setting='DISORT_ICM_'), parents=['rte_solver'], speaker='rte_solver', enable_values=("disort", )) isotropic_source_toa = option_definition.option( name='isotropic_source_toa', group='solver', helpstr='Specifies that isotropic ' 'illumination is included at top-boundary.', documentation=documentation['isotropic_source_toa'], tokens=option_definition.addSetting(name='Input.rte.fisot', setting=1), gui_inputs=(GUI_definition.FloatInput( name='isotropic_source_toa'), ), parents=['rte_solver'], speaker='rte_solver', enable_values=( "disort", "twostr", )) raman = option_definition.option( name='raman', group='solver', helpstr='Include first order rotational Raman scattering.', documentation=documentation['raman'], tokens=[ option_definition.addSetting(name='Input.raman', setting='RAMAN_CALC'), option_definition.addSetting(name='Input.ck_scheme', setting='CK_RAMAN'), option_definition.addSetting(name='Input.rte.solver', setting='SOLVER_DISORT'), option_definition.addSetting(name='Input.processing', setting='PROCESS_RAMAN'), option_definition.addLogical(name='Input.raman_original', logicals=['original'], optional=True) ], gui_inputs=(GUI_definition.ListInput(name='raman_original', valid_range=['original'], optional=True), ), parents=['rte_solver'], speaker='rte_solver', enable_values=("disort", ), ) number_of_streams = option_definition.option( name='number_of_streams', group='solver', helpstr='Number of streams.', documentation=documentation['number_of_streams'], gui_inputs=(GUI_definition.IntegerInput( name='number_of_streams'), ), tokens=option_definition.addToken(name='Input.rte.nstr', datatype=int, default=6), parents=['rte_solver'], speaker='rte_solver', enable_values=( "disort", "polradtran", ), ) polradtran = option_definition.option( name='polradtran', group='solver', helpstr='Set values for rte_solver polradtran.', documentation=documentation['polradtran'], tokens=[ option_definition.addLogical( name='id', logicals=['aziorder', 'nstokes', 'src_code'], setting='POLRADTRAN_'), option_definition.addToken(name='Input.rte.polradtran[id]', datatype=int) ], speaker='rte_solver', enable_values=('polradtran', ), showInGui=False, non_unique=True, ) polradtran_quad_type = option_definition.option( name='polradtran_quad_type', group='solver', helpstr='Type of quadrature used', documentation=documentation['polradtran_quad_type'], tokens=option_definition.addToken(name='Input.rte.pol_quad_type', valid_range=['G', 'D', 'L', 'E'], datatype=str), parents=['rte_solver'], speaker="rte_solver", enable_values=("polradtran", ), showInGui=False, ) polradtran_max_delta_tau = option_definition.option( name='polradtran_max_delta_tau', group='solver', helpstr='Initial layer thickness for doubling.', documentation=documentation['polradtran_max_delta_tau'], tokens=option_definition.addToken( name='Input.rte.pol_max_delta_tau', datatype=float, default=1e-5), parents=['rte_solver'], speaker="rte_solver", enable_values=("polradtran", ), showInGui=False, ) #no_sdisort nrefrac = conditional_enable_option( #no_sdisort name='nrefrac', #no_sdisort group='solver', #no_sdisort helpstr='Refraction for rte_solver sdisort.', #no_sdisort documentation=documentation['nrefrac'], #no_sdisort gui_inputs=(GUI_definition.IntegerListInput(name='Input.rte.nrefrac', default=0, valid_range=[0, 1, 2], optional=False),), #no_sdisort tokens=addToken('Input.rte.nrefrac', int, default=0, valid_range=[0,1,2]), #no_sdisort parents=['rte_solver'], #no_sdisort speaker="rte_solver", #no_sdisort enable_values=("sdisort",) #no_sdisort ) #no_sdisort nscat = option_definition.option( #no_sdisort name='nscat', #no_sdisort group='solver', #no_sdisort helpstr='Order of scattering.', #no_sdisort documentation=documentation['nscat'], #no_sdisort gui_inputs=(GUI_definition.IntegerInput(name='Input.rte.nscat'),), #no_sdisort tokens=addToken('Input.rte.nscat', int, default=20), #no_sdisort parents=['rte_solver'], #no_sdisort speaker="rte_solver", #no_sdisort enable_values=("sdisort",) #no_sdisort ) sdisort = option_definition.option( name='sdisort', group='solver', helpstr='Set values for rte_solver sdisort.', documentation=documentation['sdisort'], tokens=[ option_definition.addLogical( name='id', logicals=['ichapman', 'nscat', 'nrefrac'], setting='SDISORT_'), option_definition.addToken(name='Input.rte.sdisort[id]', datatype=int) ], speaker='rte_solver', enable_values=('sdisort', ), showInGui=False, non_unique=True, ) sos_nscat = option_definition.option( name='sos_nscat', group='solver', helpstr='Set order of scattering moments for rte_solver sos.', documentation=documentation['sos_nscat'], tokens=option_definition.addToken(name='Input.rte.sos_nscat', datatype=int), speaker='rte_solver', enable_values=('sos', ), showInGui=False, developer=True) deltam = option_definition.option( name='deltam', group='solver', helpstr='Turn delta-M scaling on/off.', documentation=documentation['deltam'], gui_inputs=(GUI_definition.ListInput(name='Input.rte.deltam', valid_range=['on', 'off'], optional=False, default='on'), ), tokens=option_definition.addLogical(name='Input.rte.deltam', logicals=['on', 'off'], setting='SWITCH_', default='SWITCH_ON'), parents=['rte_solver'], speaker="rte_solver", enable_values=( "disort", "twostr", )) ipa_3d = option_definition.option( name='ipa_3d', group='solver', helpstr='', documentation=documentation['ipa_3d'], tokens=option_definition.addSetting(name='Input.ipa3d', setting=1), threedmystic=True, parents=['uvspec'], non_parents=[ 'tipa', ], speaker='rte_solver', enable_values=( "disort", "twostr", "rodents", ), ) mc_tenstream = option_definition.option( name='mc_tenstream', group='solver', helpstr= 'Run Tenstream approximation solver instead of Photon Tracing. Optional argument: configuration string', documentation=documentation['mc_tenstream'], tokens=[ option_definition.addSetting(name='Input.rte.mc.tenstream', setting=1, default=0), option_definition.addToken( name='Input.rte.mc.tenstream_options', datatype=str, optional=True, default="NULL") ], parents=['uvspec'], speaker='rte_solver', enable_values=("mystic", ), threedmystic=True) mc_ipa = option_definition.option( name='mc_ipa', group='solver', helpstr='Run MYSTIC in independent pixel mode.', documentation=documentation['mc_ipa'], tokens=option_definition.addSetting(name='Input.rte.mc.ipa', setting=1, default=0), parents=['uvspec'], non_parents=[ 'mc_tipa', ], speaker='rte_solver', enable_values=("mystic", ), threedmystic=True) mc_tipa = option_definition.option( name='mc_tipa', group='solver', helpstr='Run MYSTIC in tilted independent pixel mode.', documentation=documentation['mc_tipa'], tokens=[ option_definition.addSetting(name='Input.rte.mc.ipa', setting=1), option_definition.addLogical(name='Input.rte.mc.tipa', logicals=['dirdiff', 'dir3d'], setting='TIPA_') ], parents=['uvspec'], non_parents=[ 'mc_ipa', ], speaker='rte_solver', enable_values=("mystic", ), developer=True, ) tipa = option_definition.option( name='tipa', group='solver', helpstr='Use the tilted independent pixel approximation.', documentation=documentation['tipa'], tokens=option_definition.addLogical(name='Input.tipa', logicals=['dirdiff', 'dir'], setting='TIPA_'), parents=['uvspec'], non_parents=[ 'ipa_3d', ], speaker='rte_solver', enable_values=( "rodents", 'disort', 'twostr', ), developer=True, ) sslidar = option_definition.option( name='sslidar', group='solver', helpstr='Set single scattering lidar parameters.', documentation=documentation['sslidar'], tokens=[ option_definition.addLogical( name='id', logicals=['area', 'E0', 'eff', 'position', 'range'], setting='SSLIDAR_'), option_definition.addToken(name='Input.sslidar[id]', datatype=float) ], gui_inputs=( GUI_definition.ListInput( name='id', valid_range=['area', 'e0', 'eff', 'position', 'range']), GUI_definition.FloatInput(name='Input.sslidar[id]'), ), parents=['uvspec'], speaker='rte_solver', enable_values=("sslidar", ), non_unique=True, ) sslidar_nranges = option_definition.option( name='sslidar_nranges', group='solver', helpstr='Set number fo range bins for single scattering lidar.', documentation=documentation['sslidar_nranges'], tokens=[ option_definition.addToken(name='Input.sslidar_nranges', datatype=int) ], gui_inputs=(GUI_definition.IntegerInput( name='Input.sslidar_nranges'), ), parents=['uvspec'], speaker='rte_solver', enable_values=("sslidar", ), ) sslidar_polarisation = option_definition.option( name='sslidar_polarisation', group='solver', helpstr='Turn on polarisation measurement for lidar.', documentation=documentation['sslidar_polarisation'], tokens=option_definition.addSetting( name='Input.sslidar_polarisation', setting=1), parents=['uvspec'], speaker='rte_solver', enable_values=("sslidar", ), ) tzs_cloud_top_height = option_definition.not_yet_lex2py_option( name='tzs_cloud_top_height', group='solver', helpstr='Cloud top height[s] of blackbody clouds', documentation=documentation['tzs_cloud_top_height'], tokens=option_definition.addToken(name="", datatype=str), parents=['uvspec'], speaker='rte_solver', enable_values=('tzs', ), ) # twomaxrnd3C_scale_cf = option_definition.option( # name='twomaxrnd3C_scale_cf', # group='solver', # helpstr='Scaling factor for cloud fraction split', # documentation=documentation['twomaxrnd3C_scale_cf'], # tokens=option_definition.addToken(name='Input.rte.twomaxrnd3C_scale_cf', datatype=float, default=1.0), # parents=['rte_solver'], # speaker='rte_solver', # enable_values=("twomaxrnd3C",), # ) mc_nca = option_definition.option( name='mc_nca', group='solver', helpstr= 'Neighboring Column Approximation (Klinger and Mayer 2016, 2019) for the calculation of 3d thermal heating rates', documentation=documentation['mc_nca'], tokens=[ option_definition.addSetting(name='Input.rte.mc.nca', setting=1, default=0), option_definition.addToken(name='Input.rte.mc.nca_options', datatype=str, optional=True, default="NULL") ], parents=['uvspec'], speaker='rte_solver', enable_values=("mystic", ), threedmystic=False # CK2019 added nca ) self.options = [ rte_solver, pseudospherical, disort_spherical_albedo, deltam, isotropic_source_toa, raman, mc_tenstream, mc_ipa, ipa_3d, mc_tipa, tipa, number_of_streams, disort_intcor, polradtran, polradtran_quad_type, polradtran_max_delta_tau, sslidar, sslidar_polarisation, sslidar_nranges, sdisort, sos_nscat, tzs_cloud_top_height, # twomaxrnd3C_scale_cf, mc_nca ] # CK2019 added nca
def __init__(self): documentation = get_general_atmosphere_documentation() atmos_region = option_definition.option( name='atmos_region', group='general atmosphere', helpstr='Define atmospheric region.', documentation=documentation['atmos_region'], tokens = [option_definition.addSetting(name="Input.rte.mc.backward.yes", setting=1), option_definition.addToken(name="Input.rte.mc.ixmin", datatype=int, default='NOT_DEFINED_INTEGER'), option_definition.addToken(name="Input.rte.mc.iymin", datatype=int, default='NOT_DEFINED_INTEGER'), option_definition.addToken(name="Input.rte.mc.ixmax", datatype=int, default='NOT_DEFINED_INTEGER'), option_definition.addToken(name="Input.rte.mc.iymax", datatype=int, default='NOT_DEFINED_INTEGER') ] , parents=['uvspec'], showInGui =False, threedmystic =True, ) no_absorption = option_definition.option( name='no_absorption', group='general atmosphere', helpstr='Switch off absorption.', documentation=documentation['no_absorption'], gui_inputs=(GUI_definition.TextInput(name='no_absorption',optional=True),), tokens = [option_definition.addSetting(name='ispoff', setting='get_caothoff_index(&Input.caothoff,&Input.n_caothoff, "all")'), option_definition.addToken(name='ispoff', datatype=option_definition.CaothoffType, optional=True), option_definition.addSetting(name='Input.caothoff[ispoff].no_absorption', setting=1)], parents=['uvspec'], non_unique=True, ) no_scattering = option_definition.option( name='no_scattering', group='general atmosphere', helpstr='Switch off scattering.', documentation=documentation['no_scattering'], gui_inputs=(GUI_definition.TextInput(name='no_scattering',optional=True),), tokens = [option_definition.addSetting(name='ispoff', setting='get_caothoff_index(&Input.caothoff,&Input.n_caothoff, "all")'), option_definition.addToken(name='ispoff', datatype=option_definition.CaothoffType, optional=True), option_definition.addSetting(name='Input.caothoff[ispoff].no_scattering', setting=1)], parents=['uvspec'], non_unique=True, ) interpret_as_level = option_definition.option( name='interpret_as_level', group='general atmosphere', helpstr='Interpret profile properties as level properties.', documentation=documentation['interpret_as_level'], gui_inputs=(GUI_definition.TextInput(name='Input.caothoff[isp].layer'),), tokens = [option_definition.addToken(name='isp', datatype=option_definition.CaothType), option_definition.addSetting(name='Input.caoth[isp].layer', setting='FALSE')], parents=['wc_file','ic_file','profile_file'], non_unique=True, ) zout_interpolate = option_definition.option( name='zout_interpolate', group='general_atmosphere', helpstr='Interpolate atmospheric profiles.', documentation=documentation['zout_interpolate'], tokens=option_definition.addSetting(name='Input.atm.zout_interpolate', setting='ZOUT_INTERPOLATE', default='NO_ZOUT_INTERPOLATE'), parents=['uvspec'], ) z_interpolate = option_definition.not_yet_lex2py_option( name='z_interpolate', group='general_atmosphere', documentation='', #documentation['z_interpolate'], #TODO: Missing documentation gui_inputs=(GUI_definition.TextInput(name=''),), parents=['uvspec'], non_unique=True, ) atm_z_grid = option_definition.option( name='atm_z_grid', group='atmosphere', documentation=documentation['atm_z_grid'], gui_inputs=(GUI_definition.TextInput(name='Input.atm.z_atm_forced_sea'),), tokens= [option_definition.addToken(name='Input.atm.z_atm_forced_sea', datatype=option_definition.SignedFloats), option_definition.addSetting(name='Input.atm.nz_atm_forced_sea', setting='ntokens')], parents=['uvspec'], ) reverse_atmosphere = option_definition.option( name='reverse_atmosphere', group='atmosphere', helpstr='Atmosphere is turned on the head.', documentation=documentation['reverse_atmosphere'], tokens=option_definition.addSetting(name='Input.rte.reverse', setting=1, default=0), parents=['uvspec'], ) self.options = [atmos_region, no_absorption, no_scattering, interpret_as_level, zout_interpolate, z_interpolate, atm_z_grid, reverse_atmosphere]