Dataset Information

HDFEOSVersion: "HDFEOS_V2.14"
HDF_ANNOT: "RUNTIME ENVIRONMENT INFORMATION\\012DATE OF RUN: Mon May 5 11:27:01 2008\\012HOST INFO: mag607: (Linux 2.6.9-42.ELsmp #1 SMP Tue Aug 15 10:35:26 BST 2006 x86_64)\\012RUN BY: s4pm2ops\\012UNIQUE FILE NAME: MISR_AM1_CGCL_AUG_2007_F02_0024.hdf\\012TOOLKIT_VERSION: SCF TK5.2.14\\012ENVIRONMENT VARIABLES\\012 PGSHOME = /MISR/TOOLKIT_5.2.14/TOOLKIT\\012 PGS_PC_INFO_FILE = /tmp/463662.1.MISR_OPS.q/DO.RUN_M12BP_M.2007213000000.temp\\012 PGSMSG = /MISR/OPS/S4PM-MISR-L2/strings/terra/stations/reprocessing/run_algorithm/RUNNING.RUN_M12BP_M.2007213000000/../M12BP_M/50000/MSGS\\012SMSG = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI8C#32001/\\012 Local Granule ID = MISR_AM1_AGP_P158_F01_24.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCAGP#001L0002path158000.hdf\\012LID = 1301; Local Granule ID = MISR_AM1_CSSC_F01_05.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCSSC#001C0023000.hdf\\012LID = 1307; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameDF0000000\\012LID = 1308; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameCF0000000\\012LID = 1309; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameBF0000000\\012LID = 1310; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameAF0000000\\012LID = 1311; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameAN0000000\\012LID = 1312; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameDA0000000\\012LID = 1313; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameCA0000000\\012LID = 1314; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameBA0000000\\012LID = 1315; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameAA0000000\\012LID = 1316; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameDF0000000\\012LID = 1317; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameCF0000000\\012LID = 1318; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameBF0000000\\012LID = 1319; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P158_O029983_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002080720050606180000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_AUG_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00208012005000757000.hdf\\012LID = 1500; Local Granule ID = MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0010000.hdf\\012LID = 1501; Local Granule ID = MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0021000.hdf\\012LID = 1502; Local Granule ID = MISR_AM1_ARP_INFLTCAL_T034_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00207212005002635000.hdf\\012LID = 1503; Local Granule ID = MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0022000.hdf\\012LID = 951; Local Granule ID = MISR_AM1_TC_STEREO_P158_O029983_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002080720050606180000000\\012\\012! TOA Albedo Retrieval Configuration File parameters\\012! Reference: Level 2 Top-of-Atmosphere Albedo Algorithm\\012! Theoretical Basis Document, JPL D-13401, Rev B\\012!------------------------------------------------\\0120.04 ! mu0_thresh_albedo\\012 ! minimum cosine of solar zenith angle for calculation of albedos\\0128 ! max_brf_cam_dist_t\\012 ! maximum camera distance for filling in missing side-leaving BRFs\\0121 ! max_brf_cam_dist_s\\012 ! maximum camera distance for filling in missing side-leaving BRFs\\0120.0 ! min_liquid_cloud_temp\\012 ! minimum temperature for setting cloud phase = liquid (degrees C)\\012-43.0 ! max_ice_cloud_temp\\012 ! maximum temperature for setting cloud phase = ice (degrees C)\\0126 ! min_angle_det_clear\\012 ! minimum number of angles needed for applying Deterministic (clear) model\\0120.240 0.094 0.043 0.015 ! rayleigh_std\\012 ! standard Rayleigh optical depth, for each spectral band\\0128.0 ! scale_ht\\012 ! atmospheric scale height, H (km)\\0124 ! niter_det_clear\\012 ! number of iterations for clear sky deterministic model fit\\0122.0 ! chi_sq_thresh_azm\\012 ! threshold for determining goodness of clear-sky AZM fit\\01210 ! nbin_mu\\012 ! number of cosine of zenith angle sub-bins\\01290 ! nbin_phi\\012 ! number of azimuth angle sub-bins\\0120.9 ! mu0_thresh_saw\\012 ! minimum value of mu0 above which pure Solid Angle Weighting is used\\01230.0 ! toa_altitude\\012 ! TOA altitude for referencing expansive albedos (km)\\0125 ! nblock_expansive\\012 ! number of 140.8-km blocks contributing to expansive albedo calculation\\0120 ! force_albedo_method\\012 ! force albedo code through one method: 0 - do not force; 1 - cloudy determ;\\012 ! 2 - cloudy stoch; 3 - clear determ; 4 - solid angle weighting\\0121.640 ! alb_broadband_zeropoint\\012 ! a_0 regression coefficient to use for broadband albedo calculation\\0120.170 0.210 -0.18 0.530 ! alb_broadband_coeff\\012 ! coefficients (blue-band, green-band, red-band, nir-band in order)\\012 ! to use in calculating the broadband albedo\\0121368.0 ! alb_broadband_I0b\\012 ! \"I0_b\" coefficient to use in albedo broadband calculation\\0121 ! cssc_search_dist\\012 ! distance from center of lat/long cell to search for nearest land class, \\012 ! expressed as a whole number of CSSC cells\\0128 ! min_localb_cameras\\012 ! minimum number of cameras that satisfy criteria for computing local\\012 ! albedo - to crop local albedo at swath edges\\0121 ! reset_localb_to_fill\\012 ! whether or not to reset local albedo values at filled RLRAs to BADVALUE;\\012 ! 0 = do not reset; 1 = reset\\01210000.0 ! rlp_horiz_segment_len\\012 ! horizontal distance in meters over which look vectors expressed in SOM\\012\\011 ! coords can be linearly interpolated to give acceptable results\\0122 ! rlra_filter\\012 ! type of RLRA filtering to do in RLP: 0 = do not replace RLRA BAD_VALUEs;\\012 ! 1 = replace all BAD_VALUEs with 0.0; 2 = replace all BAD_VALUES with an\\012 ! average of nearby RLRA values\\0120 ! rlra_smooth\\012 ! whether to do RLRA smoothing in RLP:\\012 ! 0 = do not smooth RLRAs; 1 = smooth RLRAs after replacement\\012, cross-track (pixels)\\0120.75 ! m2_thresh\\012 ! M2 threshold\\0121.00 ! m3_thresh\\012 ! M3 threshold\\0126 ! rs_filter_window_along\\012 ! RS filter window size, along-track direction (pixels)\\0126 ! rs_filter_window_cross\\012 ! RS filter window size, cross-track direction (pixels)\\0120 ! rs_string_size (currently not used)\\012 ! RS along-track string size (pixels)\\01250.0 ! min_median_filter_pcnt\\012 ! minimum population of filter window to perform median filtering (percent)\\0124 ! m2m3_matcher_score\\012 ! M2+M3 matcher score\\0123 ! m2_matcher_score\\012 ! M2 matcher score\\0122 ! m3_matcher_score\\012 ! M3 matcher score\\0121 ! rs_matcher_score\\012 ! RS matcher score\\0120.0 ! min_stereo_cloud_height\\012 ! minimum allowable stereoscopic cloud height. (km)\\01220.0 ! max_stereo_cloud_height\\012 ! maximum allowable stereoscopic cloud height. (km)\\0121000.0 ! max_skew\\012 ! ray skewness blunder threshold (m)\\01210000.0 ! max_skew_zerowind\\012 ! ray skewness blunder threshold (m) for zero-wind heights.\\0120 ! skew_blunder_score\\012 ! ray skewness blunder score\\0121 ! skew_lc_score\\012 ! ray skewness test low confidence score\\012275.0 ! skew_hc_thresh\\012 ! ray skewness test high confidence threshold (m)\\0122 ! skew_hc_score\\012 ! ray skewness test high confidence score\\012562.0 ! height_unc\\012 ! stereoscopic height uncertainty increment\\0128 ! max_hc_score\\012 ! maximum score for declaring a stereoscopic height High Confidence\\0126 ! min_hc_score\\012 ! minimum score for declaring a stereoscopic height High Confidence\\0125 ! max_lc_score\\012 ! maximum score for declaring a stereoscopic height Low Confidence\\0121 ! min_lc_score\\012 ! minimum score for declaring a stereoscopic height Low Confidence\\0125.0 ! max_snow_water_eq\\012 ! maximum equivalent water amount which is not considered snow-covered (mm)\\0125.0 ! max_sea_ice_pcnt\\012 ! maximum sea ice cover which is not considered snow-covered (percent)\\0120.0 ! default_rlra_ht\\012 ! default rlra height (km above terrain)\\0123.0 ! default_cloud_ht\\012 ! default cloud height (km above terrain)\\0127 ! neighborhd_size\\012 ! # of 1.1 km samples, along- and cross-track, in terrain \"neighborhood\"\\0120 3 3 2 2 ! stereo_ht_table\\0121 1 1 1 2 ! stereoscopic height decision matrix (Table 5 of ATB)\\0121 1 1 2 2 ! 0 = \"No Retrieval\"\\0121 1 1 2 2 ! 1 = \"Keep\"\\0121 1 1 2 2 ! 2 = \"Surface\"\\012 ! 3 = \"Default Cloud\"\\0120 2 2 4 4 ! sdcm_table\\0121 1 1 1 4 ! 0 = \"No Retrieval\"\\0122 2 2 4 4 ! 1 = \"CloudHC\"\\0123 3 3 4 4 ! 2 = \"CloudLC\"\\0124 3 3 4 4 ! 3 = \"Near Surface\"\\012 ! 4 = \"Clear\"\\0120.0 ! texture_max_rdqi\\012 ! RDQI thresh for determ what is valid data in calc avg BRFs and text indices\\01292.0 ! max_scat_angle\\012 ! scattering angle threshold for establishing forward scattering\\0122.0 ! max_low_cloud\\012 ! low cloud upper limit for altitude binning (km)\\0126.0 ! max_mid_cloud\\012 ! middle cloud upper limit for altitude binning (km)\\012275.0 ! cloud_thickness\\012 ! assumed cloud thickness used in cloud shadow algorithm (m)\\012550.0 ! ray_cast_step_size\\012 ! horizontal ray-casting step size in cloud and topographic shadow alg (m)\\01235.2 ! max_ray_cast\\012 ! maximum horizontal distance for casting cloud and topographic shadow\\0120.5 ! prev_match_m2_thresh\\012 ! previous match method threshold for M2\\0120.5 ! prev_match_m3_thresh\\012 ! previous match method threshold for M3\\0122 ! pyramid_levels\\012 ! number of levels in stereo image pyramid\\012.FALSE. ! rs_match_flag\\012 ! whether to use the RS stereo matching method (flag)\\0125 ! height_ref_cam\\012 ! stereo height reference camera id\\0124 ! height_comp_cam_fwd\\012 ! stereo height forward comparison camera id\\0126 ! height_comp_cam_aft\\012 ! stereo height aft comparison camera id\\0127 ! previous_window_along\\012 ! along-track size of previous-match-method search window\\0125 ! previous_window_cross\\012 ! cross-track size of previous-match-method search window\\0125 ! pyramid_window_along\\012 ! along-track size of pyramid-match-method search window\\0125 ! pyramid_window_cross\\012 ! cross-track size of pyramid-match-method search window\\0122.0 ! blunder_thresh\\012 ! number of standard deviations used to compute height blunder limits\\012275.0 ! near_ellipsoid_tolerance\\012 ! distance from ellipsoid to be considered a misregistration correction point\\01210\\011 ! min_misreg_points\\012\\011 ! min number of misreg points needed to perform misregistration correction\\0122 ! max_misreg_cross_disp\\012\\011 ! maximum cross-track disparity to allow in misregistration calculation\\0121.5 ! max_misreg_height_diff\\012\\011 ! max diff btw surface ht and disparity-calc ht for point to be included in misreg calc (times resolution)\\0122\\011 ! max_peak_variance_cross\\012\\011 ! maximum cross-track variance from histogram peak to avoid cut\\0122\\011 ! max_peak_variance_along\\012\\011 ! maximum along-track variance from histogram peak to avoid cut\\0121.00\\011 ! max_misreg_cloud_frac\\012\\011 ! max frac of domain classified as cloudy (CLOUD_HC or CLOUD_LC) for misreg calc to be performed\\0125\\011 ! misreg_srch_neighborhd\\012\\011 ! area around point to search for land (NxN)\\0123.0 ! fwdaft_windns_diff_good\\012 ! WindNS FwdAft Difference threshold for a wind to be considered good quality\\01210.0 ! fwdaft_windns_diff_bad\\012 ! WindNS FwdAft Difference threshold for a wind to be considered bad quality\\0121.0 ! fwdaft_windew_diff_good\\012 ! WindEW FwdAft Difference threshold for a wind to be considered good quality\\0123.0 ! fwdaft_windew_diff_bad\\012 ! WindEW FwdAft Difference threshold for a wind to be considered bad quality\\012300.0 ! fwdaft_wheight_diff_good\\012 ! WHeight FwdAft Difference threshold for a wind to be considered good quality\\0121000.0 ! fwdaft_wheight_diff_bad\\012 ! WHeight FwdAft Difference threshold for a wind to be considered bad quality\\01245.0 ! fwdaft_wangle_diff_bad\\012 ! WAngle FwdAft Difference threshold for a wind to be considered bad quality\\0120.30 ! ratio_ntriplets_alltriplets\\012\\011 ! min ratio of triplets to all triplets for wind disparity histograms to be used for wind QA calculations.\\01213\\011 ! wdisp_hist_width_good\\012\\011 ! max histogram width to be called good quality.\\01225\\011 ! wdisp_hist_width_bad\\012\\011 ! histogram width at or above which is called bad quality.\\0123\\011 ! min_ngoodhist_vgwind\\012\\011 ! min number of good quality histograms for wind to be very good.\\0120\\011 ! max_nbadhist_vgwind\\012\\011 ! max number of bad quality histograms for wind to be very good quality.\\0122\\011 ! min_ngoodhist_goodwind\\012\\011 ! min number of good quality histograms for wind to be good quality.\\0121\\011 ! max_nbadhist_goodwind\\012\\011 ! max number of bad quality histograms for wind to be good quality.\\0121\\011 ! min_ngoodhist_badwind\\012\\011 ! min number of good quality histograms for wind to be bad quality.\\0122\\011 ! min_nbadhist_badwind \\012\\011 ! min number of bad quality histograms for wind to be bad quality.\\0120.1 ! max_frac_bad_winds\\012 ! maximum allowable fraction of winds to fail the FwdAft quality test\\0129999.0 ! max_mean_fwdaft_diff1 \\012 ! maximum allowable mean value of NS Wind FwdAft difference for good winds\\0128.0 ! max_mean_fwdaft_diff\\012 ! maximum allowable mean value of NS Wind FwdAft difference for all winds\\0120.75 ! max_frac_bad_gdqi\\012 ! maximum allowable fraction of bad GDQI's per camera\\012\\012\\012shold for high confidence cloud percent\\012100. ! lc_cloud_pcnt_thresh\\012 ! regional cloudiness threshold for low confidence cloud percent\\0121 ! rdqi1\\012 ! maximum acceptable RDQI used in averaging data to appropriate resolution\\0123 ! rdqi2\\012 ! RDQI value to use during the comp of avg RDQI, for each RDQI > RDQI1\\012250. ! subr_topo_complex_thresh\\012 ! subregional topographic complexity threshold (m)\\01220. ! max_subr_avg_slope\\012 ! max allowable subregion average slope (degrees)\\0125 ! nsdcm_class\\012 ! number of SDCM cloud classifications\\0125 ! nrccm_class\\012 ! number of RCCM cloud classifications\\0125 ! nascm_class\\012 ! number of ASCM cloud classifications\\0123 ! nsurf_class\\012 ! number of surface classifications\\012!----------------------------------------------------------\\012! Atmospheric State Decision Matrix:\\012! cloud_mask_decision_matrix(RCCM, SDCM, ASCM, surface classification)\\012! 1 => CLEAR 2 => OPTICALLY THICK 3 => CLOUDY\\012! RCCM classifications in each row, ordered from left to right, are\\012! NotAvailabl\\004", "INPUT FILES INFORMATION\\012LID = 1101; Local Granule ID = MISR_AM1_PGE12BP_PCS_CONFIG_F01_0001.ascii\\012 Input Path = /MISR/OPS/S4PM-MISR-L2/data/ancillary/CONFIG/MISR_AM1_PGE12BP_PCS_CONFIG_F01_0001.ascii\\012LID = 2400; Local Granule ID = MISR_AM1_CGAL_AUG_2007_F05_0023.hdf\\012 Input Path = /tmp/463662.1.MISR_OPS.q/MIL3MAL.A2007213.0000.005.2008056195418.23.hdf\\012LID = 2800; Local Granule ID = MISR_AM1_CGCL_AUG_2007_F03_0023.hdf\\012 Input Path = /tmp/463662.1.MISR_OPS.q/MIL3MCLD.A2007213.0000.001.2008056201245.23.hdf\\0120000/../M12BP_M/50000/MSGS\\012SMSG = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI8C#32001/\\012 Local Granule ID = MISR_AM1_AGP_P158_F01_24.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCAGP#001L0002path158000.hdf\\012LID = 1301; Local Granule ID = MISR_AM1_CSSC_F01_05.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCSSC#001C0023000.hdf\\012LID = 1307; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameDF0000000\\012LID = 1308; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameCF0000000\\012LID = 1309; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameBF0000000\\012LID = 1310; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameAF0000000\\012LID = 1311; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameAN0000000\\012LID = 1312; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameDA0000000\\012LID = 1313; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameCA0000000\\012LID = 1314; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameBA0000000\\012LID = 1315; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P158_O029983_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00308072005060618AssociatedSensorShortNameAA0000000\\012LID = 1316; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameDF0000000\\012LID = 1317; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameCF0000000\\012LID = 1318; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameBF0000000\\012LID = 1319; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P158_O029983_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002080720050606180000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_AUG_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00208012005000757000.hdf\\012LID = 1500; Local Granule ID = MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0010000.hdf\\012LID = 1501; Local Granule ID = MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0021000.hdf\\012LID = 1502; Local Granule ID = MISR_AM1_ARP_INFLTCAL_T034_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00207212005002635000.hdf\\012LID = 1503; Local Granule ID = MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0022000.hdf\\012LID = 951; Local Granule ID = MISR_AM1_TC_STEREO_P158_O029983_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002080720050606180000000\\012\\012! TOA Albedo Retrieval Configuration File parameters\\012! Reference: Level 2 Top-of-Atmosphere Albedo Algorithm\\012! Theoretical Basis Document, JPL D-13401, Rev B\\012!------------------------------------------------\\0120.04 ! mu0_thresh_albedo\\012 ! minimum cosine of solar zenith angle for calculation of albedos\\0128 ! max_brf_cam_dist_t\\012 ! maximum camera distance for filling in missing side-leaving BRFs\\0121 ! max_brf_cam_dist_s\\012 ! maximum camera distance for filling in missing side-leaving BRFs\\0120.0 ! min_liquid_cloud_temp\\012 ! minimum temperature for setting cloud phase = liquid (degrees C)\\012-43.0 ! max_ice_cloud_temp\\012 ! maximum temperature for setting cloud phase = ice (degrees C)\\0126 ! min_angle_det_clear\\012 ! minimum number of angles needed for applying Deterministic (clear) model\\0120.240 0.094 0.043 0.015 ! rayleigh_std\\012 ! standard Rayleigh optical depth, for each spectral band\\0128.0 ! scale_ht\\012 ! atmospheric scale height, H (km)\\0124 ! niter_det_clear\\012 ! number of iterations for clear sky deterministic model fit\\0122.0 ! chi_sq_thresh_azm\\012 ! threshold for determining goodness of clear-sky AZM fit\\01210 ! nbin_mu\\012 ! number of cosine of zenith angle sub-bins\\01290 ! nbin_phi\\012 ! number of azimuth angle sub-bins\\0120.9 ! mu0_thresh_saw\\012 ! minimum value of mu0 above which pure Solid Angle Weighting is used\\01230.0 ! toa_altitude\\012 ! TOA altitude for referencing expansive albedos (km)\\0125 ! nblock_expansive\\012 ! number of 140.8-km blocks contributing to expansive albedo calculation\\0120 ! force_albedo_method\\012 ! force albedo code through one method: 0 - do not force; 1 - cloudy determ;\\012 ! 2 - cloudy stoch; 3 - clear determ; 4 - solid angle weighting\\0121.640 ! alb_broadband_zeropoint\\012 ! a_0 regression coefficient to use for broadband albedo calculation\\0120.170 0.210 -0.18 0.530 ! alb_broadband_coeff\\012 ! coefficients (blue-band, green-band, red-band, nir-band in order)\\012 ! to use in calculating the broadband albedo\\0121368.0 ! alb_broadband_I0b\\012 ! \"I0_b\" coefficient to use in albedo broadband calculation\\0121 ! cssc_search_dist\\012 ! distance from center of lat/long cell to search for nearest land class, \\012 ! expressed as a whole number of CSSC cells\\0128 ! min_localb_cameras\\012 ! minimum number of cameras that satisfy criteria for computing local\\012 ! albedo - to crop local albedo at swath edges\\0121 ! reset_localb_to_fill\\012 ! whether or not to reset local albedo values at filled RLRAs to BADVALUE;\\012 ! 0 = do not reset; 1 = reset\\01210000.0 ! rlp_horiz_segment_len\\012 ! horizontal distance in meters over which look vectors expressed in SOM\\012\\011 ! coords can be linearly interpolated to give acceptable results\\0122 ! rlra_filter\\012 ! type of RLRA filtering to do in RLP: 0 = do not replace RLRA BAD_VALUEs;\\012 ! 1 = replace all BAD_VALUEs with 0.0; 2 = replace all BAD_VALUES with an\\012 ! average of nearby RLRA values\\0120 ! rlra_smooth\\012 ! whether to do RLRA smoothing in RLP:\\012 ! 0 = do not smooth RLRAs; 1 = smooth RLRAs after replacement\\012, cross-track (pixels)\\0120.75 ! m2_thresh\\012 ! M2 threshold\\0121.00 ! m3_thresh\\012 ! M3 threshold\\0126 ! rs_filter_window_along\\012 ! RS filter window size, along-track direction (pixels)\\0126 ! rs_filter_window_cross\\012 ! RS filter window size, cross-track direction (pixels)\\0120 ! rs_string_size (currently not used)\\012 ! RS along-track string size (pixels)\\01250.0 ! min_median_filter_pcnt\\012 ! minimum population of filter window to perform median filtering (percent)\\0124 ! m2m3_matcher_score\\012 ! M2+M3 matcher score\\0123 ! m2_matcher_score\\012 ! M2 matcher score\\0122 ! m3_matcher_score\\012 ! M3 matcher score\\0121 ! rs_matcher_score\\012 ! RS matcher score\\0120.0 ! min_stereo_cloud_height\\012 ! minimum allowable stereoscopic cloud height. (km)\\01220.0 ! max_stereo_cloud_height\\012 ! maximum allowable stereoscopic cloud height. (km)\\0121000.0 ! max_skew\\012 ! ray skewness blunder threshold (m)\\01210000.0 ! max_skew_zerowind\\012 ! ray skewness blunder threshold (m) for zero-wind heights.\\0120 ! skew_blunder_score\\012 ! ray skewness blunder score\\0121 ! skew_lc_score\\012 ! ray skewness test low confidence score\\012275.0 ! skew_hc_thresh\\012 ! ray skewness test high confidence threshold (m)\\0122 ! skew_hc_score\\012 ! ray skewness test high confidence score\\012562.0 ! height_unc\\012 ! stereoscopic height uncertainty increment\\0128 ! max_hc_score\\012 ! maximum score for declaring a stereoscopic height High Confidence\\0126 ! min_hc_score\\012 ! minimum score for declaring a stereoscopic height High Confidence\\0125 ! max_lc_score\\012 ! maximum score for declaring a stereoscopic height Low Confidence\\0121 ! min_lc_score\\012 ! minimum score for declaring a stereoscopic height Low Confidence\\0125.0 ! max_snow_water_eq\\012 ! maximum equivalent water amount which is not considered snow-covered (mm)\\0125.0 ! max_sea_ice_pcnt\\012 ! maximum sea ice cover which is not considered snow-covered (percent)\\0120.0 ! default_rlra_ht\\012 ! default rlra height (km above terrain)\\0123.0 ! default_cloud_ht\\012 ! default cloud height (km above terrain)\\0127 ! neighborhd_size\\012 ! # of 1.1 km samples, along- and cross-track, in terrain \"neighborhood\"\\0120 3 3 2 2 ! stereo_ht_table\\0121 1 1 1 2 ! stereoscopic height decision matrix (Table 5 of ATB)\\0121 1 1 2 2 ! 0 = \"No Retrieval\"\\0121 1 1 2 2 ! 1 = \"Keep\"\\0121 1 1 2 2 ! 2 = \"Surface\"\\012 ! 3 = \"Default Cloud\"\\0120 2 2 4 4 ! sdcm_table\\0121 1 1 1 4 ! 0 = \"No Retrieval\"\\0122 2 2 4 4 ! 1 = \"CloudHC\"\\0123 3 3 4 4 ! 2 = \"CloudLC\"\\0124 3 3 4 4 ! 3 = \"Near Surface\"\\012 ! 4 = \"Clear\"\\0120.0 ! texture_max_rdqi\\012 ! RDQI thresh for determ what is valid data in calc avg BRFs and text indices\\01292.0 ! max_scat_angle\\012 ! scattering angle threshold for establishing forward scattering\\0122.0 ! max_low_cloud\\012 ! low cloud upper limit for altitude binning (km)\\0126.0 ! max_mid_cloud\\012 ! middle cloud upper limit for altitude binning (km)\\012275.0 ! cloud_thickness\\012 ! assumed cloud thickness used in cloud shadow algorithm (m)\\012550.0 ! ray_cast_step_size\\012 ! horizontal ray-casting step size in cloud and topographic shadow alg (m)\\01235.2 ! max_ray_cast\\012 ! maximum horizontal distance for casting cloud and topographic shadow\\0120.5 ! prev_match_m2_thresh\\012 ! previous match method threshold for M2\\0120.5 ! prev_match_m3_thresh\\012 ! previous match method threshold for M3\\0122 ! pyramid_levels\\012 ! number of levels in stereo image pyramid\\012.FALSE. ! rs_match_flag\\012 ! whether to use the RS stereo matching method (flag)\\0125 ! height_ref_cam\\012 ! stereo height reference camera id\\0124 ! height_comp_cam_fwd\\012 ! stereo height forward comparison camera id\\0126 ! height_comp_cam_aft\\012 ! stereo height aft comparison camera id\\0127 ! previous_window_along\\012 ! along-track size of previous-match-method search window\\0125 ! previous_window_cross\\012 ! cross-track size of previous-match-method search window\\0125 ! pyramid_window_along\\012 ! along-track size of pyramid-match-method search window\\0125 ! pyramid_window_cross\\012 ! cross-track size of pyramid-match-method search window\\0122.0 ! blunder_thresh\\012 ! number of standard deviations used to compute height blunder limits\\012275.0 ! near_ellipsoid_tolerance\\012 ! distance from ellipsoid to be considered a misregistration correction point\\01210\\011 ! min_misreg_points\\012\\011 ! min number of misreg points needed to perform misregistration correction\\0122 ! max_misreg_cross_disp\\012\\011 ! maximum cross-track disparity to allow in misregistration calculation\\0121.5 ! max_misreg_height_diff\\012\\011 ! max diff btw surface ht and disparity-calc ht for point to be included in misreg calc (times resolution)\\0122\\011 ! max_peak_variance_cross\\012\\011 ! maximum cross-track variance from histogram peak to avoid cut\\0122\\011 ! max_peak_variance_along\\012\\011 ! maximum along-track variance from histogram peak to avoid cut\\0121.00\\011 ! max_misreg_cloud_frac\\012\\011 ! max frac of domain classified as cloudy (CLOUD_HC or CLOUD_LC) for misreg calc to be performed\\0125\\011 ! misreg_srch_neighborhd\\012\\011 ! area around point to search for land (NxN)\\0123.0 ! fwdaft_windns_diff_good\\012 ! WindNS FwdAft Difference threshold for a wind to be considered good quality\\01210.0 ! fwdaft_windns_diff_bad\\012 ! WindNS FwdAft Difference threshold for a wind to be considered bad quality\\0121.0 ! fwdaft_windew_diff_good\\012 ! WindEW FwdAft Difference threshold for a wind to be considered good quality\\0123.0 ! fwdaft_windew_diff_bad\\012 ! WindEW FwdAft Difference threshold for a wind to be considered bad quality\\012300.0 ! fwdaft_wheight_diff_good\\012 ! WHeight FwdAft Difference threshold for a wind to be considered good quality\\0121000.0 ! fwdaft_wheight_diff_bad\\012 ! WHeight FwdAft Difference threshold for a wind to be considered bad quality\\01245.0 ! fwdaft_wangle_diff_bad\\012 ! WAngle FwdAft Difference threshold for a wind to be considered bad quality\\0120.30 ! ratio_ntriplets_alltriplets\\012\\011 ! min ratio of triplets to all triplets for wind disparity histograms to be used for wind QA calculations.\\01213\\011 ! wdisp_hist_width_good\\012\\011 ! max histogram width to be called good quality.\\01225\\011 ! wdisp_hist_width_bad\\012\\011 ! histogram width at or above which is called bad quality.\\0123\\011 ! min_ngoodhist_vgwind\\012\\011 ! min number of good quality histograms for wind to be very good.\\0120\\011 ! max_nbadhist_vgwind\\012\\011 ! max number of bad quality histograms for wind to be very good quality.\\0122\\011 ! min_ngoodhist_goodwind\\012\\011 ! min number of good quality histograms for wind to be good quality.\\0121\\011 ! max_nbadhist_goodwind\\012\\011 ! max number of bad quality histograms for wind to be good quality.\\0121\\011 ! min_ngoodhist_badwind\\012\\011 ! min number of good quality histograms for wind to be bad quality.\\0122\\011 ! min_nbadhist_badwind \\012\\011 ! min number of bad quality histograms for wind to be bad quality.\\0120.1 ! max_frac_bad_winds\\012 ! maximum allowable fraction of winds to fail the FwdAft quality test\\0129999.0 ! max_mean_fwdaft_diff1 \\012 ! maximum allowable mean value of NS Wind FwdAft difference for good winds\\0128.0 ! max_mean_fwdaft_diff\\012 ! maximum allowable mean value of NS Wind FwdAft difference for all winds\\0120.75 ! max_frac_bad_gdqi\\012 ! maximum allowable fraction of bad GDQI's per camera\\012\\012\\012shold for high confidence cloud percent\\012100. ! lc_cloud_pcnt_thresh\\012 ! regional cloudiness threshold for low confidence cloud percent\\0121 ! rdqi1\\012 ! maximum acceptable RDQI used in averaging data to appropriate resolution\\0123 ! rdqi2\\012 ! RDQI value to use during the comp of avg RDQI, for each RDQI > RDQI1\\012250. ! subr_topo_complex_thresh\\012 ! subregional topographic complexity threshold (m)\\01220. ! max_subr_avg_slope\\012 ! max allowable subregion average slope (degrees)\\0125 ! nsdcm_class\\012 ! number of SDCM cloud classifications\\0125 ! nrccm_class\\012 ! number of RCCM cloud classifications\\0125 ! nascm_class\\012 ! number of ASCM cloud classifications\\0123 ! nsurf_class\\012 ! number of surface classifications\\012!----------------------------------------------------------\\012! Atmospheric State Decision Matrix:\\012! cloud_mask_decision_matrix(RCCM, SDCM, ASCM, surface classification)\\012! 1 => CLEAR 2 => OPTICALLY THICK 3 => CLOUDY\\012! RCCM classifications in each row, ordered from left to right, are\\012! 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Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P158_O029983_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00308072005060618AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P158_O029983_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00408072005060618AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P158_O029983_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002080720050606180000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_AUG_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00208012005000757000.hdf\\012LID = 1500; Local Granule ID = MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0010000.hdf\\012LID = 1501; Local Granule ID = MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0021000.hdf\\012LID = 1502; Local Granule ID = MISR_AM1_ARP_INFLTCAL_T034_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00207212005002635000.hdf\\012LID = 1503; Local Granule ID = MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#001C0022000.hdf\\012LID = 951; Local Granule ID = MISR_AM1_TC_STEREO_P158_O029983_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002080720050606180000000\\012\\012! TOA Albedo Retrieval Configuration File parameters\\012! Reference: Level 2 Top-of-Atmosphere Albedo Algorithm\\012! Theoretical Basis Document, JPL D-13401, Rev B\\012!------------------------------------------------\\0120.04 ! mu0_thresh_albedo\\012 ! minimum cosine of solar zenith angle for calculation of albedos\\0128 ! max_brf_cam_dist_t\\012 ! maximum camera distance for filling in missing side-leaving BRFs\\0121 ! max_brf_cam_dist_s\\012 ! maximum camera distance for filling in missing side-leaving BRFs\\0120.0 ! min_liquid_cloud_temp\\012 ! minimum temperature for setting cloud phase = liquid (degrees C)\\012-43.0 ! max_ice_cloud_temp\\012 ! maximum temperature for setting cloud phase = ice (degrees C)\\0126 ! min_angle_det_clear\\012 ! minimum number of angles needed for applying Deterministic (clear) model\\0120.240 0.094 0.043 0.015 ! rayleigh_std\\012 ! standard Rayleigh optical depth, for each spectral band\\0128.0 ! scale_ht\\012 ! atmospheric scale height, H (km)\\0124 ! niter_det_clear\\012 ! number of iterations for clear sky deterministic model fit\\0122.0 ! chi_sq_thresh_azm\\012 ! threshold for determining goodness of clear-sky AZM fit\\01210 ! nbin_mu\\012 ! number of cosine of zenith angle sub-bins\\01290 ! nbin_phi\\012 ! number of azimuth angle sub-bins\\0120.9 ! mu0_thresh_saw\\012 ! minimum value of mu0 above which pure Solid Angle Weighting is used\\01230.0 ! toa_altitude\\012 ! TOA altitude for referencing expansive albedos (km)\\0125 ! nblock_expansive\\012 ! number of 140.8-km blocks contributing to expansive albedo calculation\\0120 ! force_albedo_method\\012 ! force albedo code through one method: 0 - do not force; 1 - cloudy determ;\\012 ! 2 - cloudy stoch; 3 - clear determ; 4 - solid angle weighting\\0121.640 ! alb_broadband_zeropoint\\012 ! a_0 regression coefficient to use for broadband albedo calculation\\0120.170 0.210 -0.18 0.530 ! alb_broadband_coeff\\012 ! coefficients (blue-band, green-band, red-band, nir-band in order)\\012 ! to use in calculating the broadband albedo\\0121368.0 ! alb_broadband_I0b\\012 ! \"I0_b\" coefficient to use in albedo broadband calculation\\0121 ! cssc_search_dist\\012 ! distance from center of lat/long cell to search for nearest land class, \\012 ! expressed as a whole number of CSSC cells\\0128 ! min_localb_cameras\\012 ! minimum number of cameras that satisfy criteria for computing local\\012 ! albedo - to crop local albedo at swath edges\\0121 ! reset_localb_to_fill\\012 ! whether or not to reset local albedo values at filled RLRAs to BADVALUE;\\012 ! 0 = do not reset; 1 = reset\\01210000.0 ! rlp_horiz_segment_len\\012 ! horizontal distance in meters over which look vectors expressed in SOM\\012\\011 ! coords can be linearly interpolated to give acceptable results\\0122 ! rlra_filter\\012 ! type of RLRA filtering to do in RLP: 0 = do not replace RLRA BAD_VALUEs;\\012 ! 1 = replace all BAD_VALUEs with 0.0; 2 = replace all BAD_VALUES with an\\012 ! average of nearby RLRA values\\0120 ! rlra_smooth\\012 ! whether to do RLRA smoothing in RLP:\\012 ! 0 = do not smooth RLRAs; 1 = smooth RLRAs after replacement\\012, cross-track (pixels)\\0120.75 ! m2_thresh\\012 ! M2 threshold\\0121.00 ! m3_thresh\\012 ! M3 threshold\\0126 ! rs_filter_window_along\\012 ! RS filter window size, along-track direction (pixels)\\0126 ! rs_filter_window_cross\\012 ! RS filter window size, cross-track direction (pixels)\\0120 ! rs_string_size (currently not used)\\012 ! RS along-track string size (pixels)\\01250.0 ! min_median_filter_pcnt\\012 ! minimum population of filter window to perform median filtering (percent)\\0124 ! m2m3_matcher_score\\012 ! M2+M3 matcher score\\0123 ! m2_matcher_score\\012 ! M2 matcher score\\0122 ! m3_matcher_score\\012 ! M3 matcher score\\0121 ! rs_matcher_score\\012 ! RS matcher score\\0120.0 ! min_stereo_cloud_height\\012 ! minimum allowable stereoscopic cloud height. (km)\\01220.0 ! max_stereo_cloud_height\\012 ! maximum allowable stereoscopic cloud height. (km)\\0121000.0 ! max_skew\\012 ! ray skewness blunder threshold (m)\\01210000.0 ! max_skew_zerowind\\012 ! ray skewness blunder threshold (m) for zero-wind heights.\\0120 ! skew_blunder_score\\012 ! ray skewness blunder score\\0121 ! skew_lc_score\\012 ! ray skewness test low confidence score\\012275.0 ! skew_hc_thresh\\012 ! ray skewness test high confidence threshold (m)\\0122 ! skew_hc_score\\012 ! ray skewness test high confidence score\\012562.0 ! height_unc\\012 ! stereoscopic height uncertainty increment\\0128 ! max_hc_score\\012 ! maximum score for declaring a stereoscopic height High Confidence\\0126 ! min_hc_score\\012 ! minimum score for declaring a stereoscopic height High Confidence\\0125 ! max_lc_score\\012 ! maximum score for declaring a stereoscopic height Low Confidence\\0121 ! min_lc_score\\012 ! minimum score for declaring a stereoscopic height Low Confidence\\0125.0 ! max_snow_water_eq\\012 ! maximum equivalent water amount which is not considered snow-covered (mm)\\0125.0 ! max_sea_ice_pcnt\\012 ! maximum sea ice cover which is not considered snow-covered (percent)\\0120.0 ! default_rlra_ht\\012 ! default rlra height (km above terrain)\\0123.0 ! default_cloud_ht\\012 ! default cloud height (km above terrain)\\0127 ! neighborhd_size\\012 ! # of 1.1 km samples, along- and cross-track, in terrain \"neighborhood\"\\0120 3 3 2 2 ! stereo_ht_table\\0121 1 1 1 2 ! stereoscopic height decision matrix (Table 5 of ATB)\\0121 1 1 2 2 ! 0 = \"No Retrieval\"\\0121 1 1 2 2 ! 1 = \"Keep\"\\0121 1 1 2 2 ! 2 = \"Surface\"\\012 ! 3 = \"Default Cloud\"\\0120 2 2 4 4 ! sdcm_table\\0121 1 1 1 4 ! 0 = \"No Retrieval\"\\0122 2 2 4 4 ! 1 = \"CloudHC\"\\0123 3 3 4 4 ! 2 = \"CloudLC\"\\0124 3 3 4 4 ! 3 = \"Near Surface\"\\012 ! 4 = \"Clear\"\\0120.0 ! texture_max_rdqi\\012 ! RDQI thresh for determ what is valid data in calc avg BRFs and text indices\\01292.0 ! max_scat_angle\\012 ! scattering angle threshold for establishing forward scattering\\0122.0 ! max_low_cloud\\012 ! low cloud upper limit for altitude binning (km)\\0126.0 ! max_mid_cloud\\012 ! middle cloud upper limit for altitude binning (km)\\012275.0 ! cloud_thickness\\012 ! assumed cloud thickness used in cloud shadow algorithm (m)\\012550.0 ! ray_cast_step_size\\012 ! horizontal ray-casting step size in cloud and topographic shadow alg (m)\\01235.2 ! max_ray_cast\\012 ! maximum horizontal distance for casting cloud and topographic shadow\\0120.5 ! prev_match_m2_thresh\\012 ! previous match method threshold for M2\\0120.5 ! prev_match_m3_thresh\\012 ! previous match method threshold for M3\\0122 ! pyramid_levels\\012 ! number of levels in stereo image pyramid\\012.FALSE. ! rs_match_flag\\012 ! whether to use the RS stereo matching method (flag)\\0125 ! height_ref_cam\\012 ! stereo height reference camera id\\0124 ! height_comp_cam_fwd\\012 ! stereo height forward comparison camera id\\0126 ! height_comp_cam_aft\\012 ! stereo height aft comparison camera id\\0127 ! previous_window_along\\012 ! along-track size of previous-match-method search window\\0125 ! previous_window_cross\\012 ! cross-track size of previous-match-method search window\\0125 ! pyramid_window_along\\012 ! along-track size of pyramid-match-method search window\\0125 ! pyramid_window_cross\\012 ! cross-track size of pyramid-match-method search window\\0122.0 ! blunder_thresh\\012 ! number of standard deviations used to compute height blunder limits\\012275.0 ! near_ellipsoid_tolerance\\012 ! distance from ellipsoid to be considered a misregistration correction point\\01210\\011 ! min_misreg_points\\012\\011 ! min number of misreg points needed to perform misregistration correction\\0122 ! max_misreg_cross_disp\\012\\011 ! maximum cross-track disparity to allow in misregistration calculation\\0121.5 ! max_misreg_height_diff\\012\\011 ! max diff btw surface ht and disparity-calc ht for point to be included in misreg calc (times resolution)\\0122\\011 ! max_peak_variance_cross\\012\\011 ! maximum cross-track variance from histogram peak to avoid cut\\0122\\011 ! max_peak_variance_along\\012\\011 ! maximum along-track variance from histogram peak to avoid cut\\0121.00\\011 ! max_misreg_cloud_frac\\012\\011 ! max frac of domain classified as cloudy (CLOUD_HC or CLOUD_LC) for misreg calc to be performed\\0125\\011 ! misreg_srch_neighborhd\\012\\011 ! area around point to search for land (NxN)\\0123.0 ! fwdaft_windns_diff_good\\012 ! WindNS FwdAft Difference threshold for a wind to be considered good quality\\01210.0 ! fwdaft_windns_diff_bad\\012 ! WindNS FwdAft Difference threshold for a wind to be considered bad quality\\0121.0 ! fwdaft_windew_diff_good\\012 ! WindEW FwdAft Difference threshold for a wind to be considered good quality\\0123.0 ! fwdaft_windew_diff_bad\\012 ! WindEW FwdAft Difference threshold for a wind to be considered bad quality\\012300.0 ! fwdaft_wheight_diff_good\\012 ! WHeight FwdAft Difference threshold for a wind to be considered good quality\\0121000.0 ! fwdaft_wheight_diff_bad\\012 ! WHeight FwdAft Difference threshold for a wind to be considered bad quality\\01245.0 ! fwdaft_wangle_diff_bad\\012 ! WAngle FwdAft Difference threshold for a wind to be considered bad quality\\0120.30 ! ratio_ntriplets_alltriplets\\012\\011 ! min ratio of triplets to all triplets for wind disparity histograms to be used for wind QA calculations.\\01213\\011 ! wdisp_hist_width_good\\012\\011 ! max histogram width to be called good quality.\\01225\\011 ! wdisp_hist_width_bad\\012\\011 ! histogram width at or above which is called bad quality.\\0123\\011 ! min_ngoodhist_vgwind\\012\\011 ! min number of good quality histograms for wind to be very good.\\0120\\011 ! max_nbadhist_vgwind\\012\\011 ! max number of bad quality histograms for wind to be very good quality.\\0122\\011 ! min_ngoodhist_goodwind\\012\\011 ! min number of good quality histograms for wind to be good quality.\\0121\\011 ! max_nbadhist_goodwind\\012\\011 ! max number of bad quality histograms for wind to be good quality.\\0121\\011 ! min_ngoodhist_badwind\\012\\011 ! min number of good quality histograms for wind to be bad quality.\\0122\\011 ! min_nbadhist_badwind \\012\\011 ! min number of bad quality histograms for wind to be bad quality.\\0120.1 ! max_frac_bad_winds\\012 ! maximum allowable fraction of winds to fail the FwdAft quality test\\0129999.0 ! max_mean_fwdaft_diff1 \\012 ! maximum allowable mean value of NS Wind FwdAft difference for good winds\\0128.0 ! max_mean_fwdaft_diff\\012 ! maximum allowable mean value of NS Wind FwdAft difference for all winds\\0120.75 ! max_frac_bad_gdqi\\012 ! maximum allowable fraction of bad GDQI's per camera\\012\\012\\012shold for high confidence cloud percent\\012100. ! lc_cloud_pcnt_thresh\\012 ! regional cloudiness threshold for low confidence cloud percent\\0121 ! rdqi1\\012 ! maximum acceptable RDQI used in averaging data to appropriate resolution\\0123 ! rdqi2\\012 ! RDQI value to use during the comp of avg RDQI, for each RDQI > RDQI1\\012250. ! subr_topo_complex_thresh\\012 ! subregional topographic complexity threshold (m)\\01220. ! max_subr_avg_slope\\012 ! max allowable subregion average slope (degrees)\\0125 ! nsdcm_class\\012 ! number of SDCM cloud classifications\\0125 ! nrccm_class\\012 ! number of RCCM cloud classifications\\0125 ! nascm_class\\012 ! number of ASCM cloud classifications\\0123 ! nsurf_class\\012 ! number of surface classifications\\012!----------------------------------------------------------\\012! Atmospheric State Decision Matrix:\\012! cloud_mask_decision_matrix(RCCM, SDCM, ASCM, surface classification)\\012! 1 => CLEAR 2 => OPTICALLY THICK 3 => CLOUDY\\012! RCCM classifications in each row, ordered from left to right, are\\012! NotAvailabl\\004"

Variables in this Dataset

CloudAverage: Structure
Data Fields: Structure
Average fill flag: Array of 32 bit Integers [YDim:CloudAverage = 0..359][XDim:CloudAverage = 0..719]
_FillValue: 0
Stereo height bin average: Array of 32 bit Reals [YDim:CloudAverage = 0..359][XDim:CloudAverage = 0..719][HeightBin:CloudAverage = 0..14][WindType:CloudAverage = 0..1]
_FillValue: -9999
Stereo height histogram: Array of 32 bit Integers [YDim:CloudAverage = 0..359][XDim:CloudAverage = 0..719][HeightBin:CloudAverage = 0..14][WindType:CloudAverage = 0..1]
_FillValue: 0
CloudWindAverage: Structure
Data Fields: Structure
Average fill flag - Wind: Array of 32 bit Integers [YDim:CloudWindAverage = 0..71][XDim:CloudWindAverage = 0..143]
_FillValue: 0
Wind speed average: Array of 32 bit Reals [YDim:CloudWindAverage = 0..71][XDim:CloudWindAverage = 0..143][HeightBin:CloudWindAverage = 0..14][WindIndex:CloudWindAverage = 0..2]
_FillValue: -9999
Wind speed standard deviation: Array of 32 bit Reals [YDim:CloudWindAverage = 0..71][XDim:CloudWindAverage = 0..143][HeightBin:CloudWindAverage = 0..14][WindIndex:CloudWindAverage = 0..2]
_FillValue: 0
Wind speed swath count: Array of 32 bit Integers [YDim:CloudWindAverage = 0..71][XDim:CloudWindAverage = 0..143][HeightBin:CloudWindAverage = 0..14][WindIndex:CloudWindAverage = 0..2]
_FillValue: 0
Source file: Sequence
Orbit number: Structure
Orbit number__0: 32 bit Integer
Path number: Structure
Path number__0: Byte
Local Granule Id: Structure
Local Granule Id__0: String
Local Version Id: Structure
Local Version Id__0: String
CloudType Enumeration: Sequence
Value: Structure
Value__0: String
HeightBin Enumeration: Sequence
Value: Structure
Value__0: String
WindType Enumeration: Sequence
Value: Structure
Value__0: String
WindIndex Enumeration: Sequence
Value: Structure
Value__0: String
Wind speed swath count Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Wind speed standard deviation Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Wind speed average Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Stereo height bin average Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Stereo height histogram Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Average fill flag - Wind Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Average fill flag Statistic: Sequence
Minimum: Structure
Minimum__0: 32 bit Real
Maximum: Structure
Maximum__0: 32 bit Real
Mean: Structure
Mean__0: 32 bit Real
Standard Deviation: Structure
Standard Deviation__0: 32 bit Real
Count: Structure
Count__0: 32 bit Integer
Time of Observations CloudWindAverage: Sequence
Latitude Index: Structure
Latitude Index__0: 16 bit Integer
Longitude Index: Structure
Longitude Index__0: 16 bit Integer
Orbit: Structure
Orbit__0: 32 bit Integer
Path: Structure
Path__0: Byte
Year: Structure
Year__0: Byte
Month: Structure
Month__0: Byte
Day: Structure
Day__0: Byte
Hour: Structure
Hour__0: Byte
Minute: Structure
Minute__0: Byte
Time of Observations CloudAverage: Sequence
Latitude Index: Structure
Latitude Index__0: 16 bit Integer
Longitude Index: Structure
Longitude Index__0: 16 bit Integer
Orbit: Structure
Orbit__0: 32 bit Integer
Path: Structure
Path__0: Byte
Year: Structure
Year__0: Byte
Month: Structure
Month__0: Byte
Day: Structure
Day__0: Byte
Hour: Structure
Hour__0: Byte
Minute: Structure
Minute__0: Byte