| Ocean_blocks.numbers: |
7, 8, 9, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24, 77, 78, 79, 80, 81, 82, 83, 84, 85, 86, 87, 88, 89, 90, 91, 92, 97, 98, 100, 101, 108, 109, 110, 111, 112, 113, 114, 115, 116, 117, 118, 119, 120, 121, 122, 123, 124, 125, 126, 127, 128, 129, 130, 131, 132, 133, 134, 135, 136, 137, 138, 139, 140, 141, 142, 143, 144, 145, 176, 177, 178, 179, 180, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0
|
| HDF_ANNOT: |
"SCIENCE CONFIGURATION INFORMATION\\012MISRFILE\\012!! Glitter angle !!\\01240.0\\012!! n1, minumum n for sigma of r3 !!\\0129\\012!! n2, minimum n for ave of r3 !!\\0129\\012!! n3, minimum n for ave of D !!\\0125\\012!! RDQI1, minimum allowable quality for sigma r3 !!\\0120\\012!! RDQI2, minimum allowable quality for ave r3 !!\\0120\\012!! Search distance finding the nearest CSSC land class !!\\01220\\012!! Number of successful bin variance threshold !!\\01264\\012!! Total population of histogram update threshold !!\\0125000\\012!! ------------------------------------------\\012!! MISR L1B3 (RCCM) Config File\\012!! F02_01\\012!! ------------------------------------------\\012PS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI8C#32001/\\012 Local Granule ID = MISR_AM1_AGP_P155_F01_24.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCAGP#001L0002path155000.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_P155_O028745_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameDF0000000\\012LID = 1308; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameCF0000000\\012LID = 1309; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameBF0000000\\012LID = 1310; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameAF0000000\\012LID = 1311; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameAN0000000\\012LID = 1312; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameDA0000000\\012LID = 1313; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameCA0000000\\012LID = 1314; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameBA0000000\\012LID = 1315; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1316; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDF0000000\\012LID = 1317; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCF0000000\\012LID = 1318; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBF0000000\\012LID = 1319; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P155_O028745_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002051420050548440000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_MAY_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00205012005012142000.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_T032_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00203212005012820000.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_P155_O028745_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002051420050548440000000\\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 along-track (pixels)\\0126 ! target_patch_cross \\012 ! target patch size used in height retrievals, 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\\012ld 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\\0121 ! water_algorithm_type\\012 ! Algorithm to use for aerosol retrievals over water. \\012 ! 1 = da\\004", "EXECUTABLE INFORMATION\\012MISR_EXEC_NAME:GP_cloud_main.c\\012MISR_EXEC_VERSION: V4.0_PGE1_13\\012MISR_COMPOSITION_INFO_BEGIN\\012DATE OF BUILD: Wed Nov 16 12:05:31 EST 2005\\012BUILT BY: sbaekins\\012HOST INFO: l0spg11: ClearCase 2003.06.10+ (IRIX64 6.5 10070055 IP35)\\012VOBS CONFIGURATION:\\012 /vobs/PCS/... V3.3\\012 /vobs/PGEvob/... V4.0\\012 /vobs/Shared/... V4.0\\012 /vobs/L1B2/... V4.0_PGE1_13\\012LIB ENVIRONMENT:\\012 HDFEOS:/vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/hdfeos/lib/sgi32\\012 HDF:/vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/hdf/sgi32/HDF4.2r0/lib\\012 PGSTK:/vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/lib/sgi32\\012COMPILER FLAGS\\012 -n32 -mips4 -r10000 -O3 -g3 -fullwarn -DCPU_SGI\\012 -Wl,-woff,84 -Wl,-woff,85 -Wl,-woff,15 -Wl,-woff,134\\012 -DCC_VERSION=MIPSpro Compilers: Version 7.4\\012 -DOSVERSION=6.5\\012MISR_COMPOSITION_INFO_END\\012CAGP#001L0002path155000.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_P155_O028745_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameDF0000000\\012LID = 1308; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameCF0000000\\012LID = 1309; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameBF0000000\\012LID = 1310; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameAF0000000\\012LID = 1311; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameAN0000000\\012LID = 1312; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameDA0000000\\012LID = 1313; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameCA0000000\\012LID = 1314; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameBA0000000\\012LID = 1315; Local Granule ID = MISR_AM1_GRP_TERRAIN_GM_P155_O028745_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2T#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1316; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDF0000000\\012LID = 1317; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCF0000000\\012LID = 1318; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBF0000000\\012LID = 1319; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P155_O028745_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002051420050548440000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_MAY_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00205012005012142000.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_T032_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00203212005012820000.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_P155_O028745_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002051420050548440000000\\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 along-track (pixels)\\0126 ! target_patch_cross \\012 ! target patch size used in height retrievals, 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\\012ld 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\\0121 ! water_algorithm_type\\012 ! Algorithm to use for aerosol retrievals over water. \\012 ! 1 = da\\004", "INPUT FILES INFORMATION\\012LID = 190; Local Granule ID = \\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/CGM/MISR_AM1_CGM_F01_0007.ascii\\012LID = 227; Local Granule ID = MISR_AM1_RCCT_SUM_AA_T919_F02_0003.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/RCCT/MISR_AM1_RCCT_SUM_AA_T919_F02_0003.hdf\\012LID = 242; Local Granule ID = MISR_AM1_RCCI_ACAM_F01_05.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/RCCI/MISR_AM1_RCCI_ACAM_F01_05.hdf\\012LID = 1301; Local Granule ID = MISR_AM1_CSSC_F01_05.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/CSSC/MISR_AM1_CSSC_F01_05.hdf\\012LID = 1304; Local Granule ID = MISR_AM1_AGP_P156_F01_24.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/AGP/MISR_AM1_AGP_P156_F01_24.hdf\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P156_O024187_F03_0013.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/MIB2GEOP/MIB2GEOP.A2004187.0556.002.2007084033740.13.hdf\\012LID = 1500; Local Granule ID = MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_static/MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012LID = 1501; Local Granule ID = MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_static/MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012LID = 1503; Local Granule ID = MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_static/MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012LID = 250; Local Granule ID = MISR_AM1_RCCM_CONFIG_AA_F02_02.ascii\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/CONFIG/MISR_AM1_RCCM_CONFIG_AA_F02_02.ascii\\012LID = 1101; Local Granule ID = MISR_AM1_PGE13_PCS_CONFIG_AA_F01_01.ascii\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/CONFIG/MISR_AM1_PGE13_PCS_CONFIG_AA_F01_01.ascii\\012LID = 1502; Local Granule ID = MISR_AM1_ARP_INFLTCAL_T027_F02_0010.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_dynamic/MISR_AM1_ARP_INFLTCAL_T027_F02_0010.hdf\\012LID = 10501; Local Granule ID = AM1EPHN0.A2004187.0400.001.2004187092511\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1EPHN0.A2004187.0400.001.2004187132513\\012LID = 10501; Local Granule ID = AM1EPHN0.A2004187.0600.001.2004187124316\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1EPHN0.A2004187.0600.001.2004187164317\\012LID = 10502; Local Granule ID = AM1ATTNF.A2004187.0400.001.2004190175809\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1ATTNF.A2004187.0400.001.2004190215809\\012LID = 10502; Local Granule ID = AM1ATTNF.A2004187.0600.001.2004190180405\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1ATTNF.A2004187.0600.001.2004190220405\\012LID = 10301; Local Granule ID = \\012 Input Path = /vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/database/common/TD/leapsec.dat\\012LID = 10401; Local Granule ID = \\012 Input Path = /vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/database/common/CSC/utcpole.dat\\012T#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1316; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDF0000000\\012LID = 1317; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCF0000000\\012LID = 1318; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBF0000000\\012LID = 1319; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P155_O028745_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002051420050548440000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_MAY_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00205012005012142000.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_T032_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00203212005012820000.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_P155_O028745_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002051420050548440000000\\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 along-track (pixels)\\0126 ! target_patch_cross \\012 ! target patch size used in height retrievals, 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\\012ld 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\\0121 ! water_algorithm_type\\012 ! Algorithm to use for aerosol retrievals over water. \\012 ! 1 = da\\004", "RUNTIME ENVIRONMENT INFORMATION\\012DATE OF RUN: Sun Mar 25 16:12:24 2007\\012HOST INFO: l0spg10: (IRIX64 6.5 01090133 IP35)\\012RUN BY: s4pmopsr\\012UNIQUE FILE NAME: MISR_AM1_GRP_RCCM_GM_P156_O024187_AA_F04_0024.hdf\\012TOOLKIT_VERSION: DAAC TK5.2.13\\012ENVIRONMENT VARIABLES\\012 PGSHOME = /vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT\\012 PGS_PC_INFO_FILE = /vol1/OPS/S4PM-MISR-REPR/strings/terra/stations/reprocessing/run_algorithm/RUNNING.RUN_M13AA.2004187055650/DO.RUN_M13AA.2004187055650\\012 PGSMSG = /vol1/OPS/S4PM-MISR-REPR/strings/terra/stations/reprocessing/run_algorithm/RUNNING.RUN_M13AA.2004187055650/../M13AA/40000/MSGS\\0125.hdf\\012LID = 1304; Local Granule ID = MISR_AM1_AGP_P156_F01_24.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/AGP/MISR_AM1_AGP_P156_F01_24.hdf\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P156_O024187_F03_0013.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/MIB2GEOP/MIB2GEOP.A2004187.0556.002.2007084033740.13.hdf\\012LID = 1500; Local Granule ID = MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_static/MISR_AM1_ARP_PRFLTCHAR_F02_0002.hdf\\012LID = 1501; Local Granule ID = MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_static/MISR_AM1_ARP_PRFLTCAL_F02_0005.hdf\\012LID = 1503; Local Granule ID = MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_static/MISR_AM1_ARP_CONFIG_F03_0003.hdf\\012LID = 250; Local Granule ID = MISR_AM1_RCCM_CONFIG_AA_F02_02.ascii\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/CONFIG/MISR_AM1_RCCM_CONFIG_AA_F02_02.ascii\\012LID = 1101; Local Granule ID = MISR_AM1_PGE13_PCS_CONFIG_AA_F01_01.ascii\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/CONFIG/MISR_AM1_PGE13_PCS_CONFIG_AA_F01_01.ascii\\012LID = 1502; Local Granule ID = MISR_AM1_ARP_INFLTCAL_T027_F02_0010.hdf\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/ancillary/ARP_dynamic/MISR_AM1_ARP_INFLTCAL_T027_F02_0010.hdf\\012LID = 10501; Local Granule ID = AM1EPHN0.A2004187.0400.001.2004187092511\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1EPHN0.A2004187.0400.001.2004187132513\\012LID = 10501; Local Granule ID = AM1EPHN0.A2004187.0600.001.2004187124316\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1EPHN0.A2004187.0600.001.2004187164317\\012LID = 10502; Local Granule ID = AM1ATTNF.A2004187.0400.001.2004190175809\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1ATTNF.A2004187.0400.001.2004190215809\\012LID = 10502; Local Granule ID = AM1ATTNF.A2004187.0600.001.2004190180405\\012 Input Path = /vol1/OPS/S4PM-MISR-REPR/data/INPUT/AM1ATTNF.A2004187.0600.001.2004190220405\\012LID = 10301; Local Granule ID = \\012 Input Path = /vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/database/common/TD/leapsec.dat\\012LID = 10401; Local Granule ID = \\012 Input Path = /vol1/TS1/ssit/TOOLKIT_5.2.13/TOOLKIT/database/common/CSC/utcpole.dat\\012T#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1316; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDF0000000\\012LID = 1317; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCF0000000\\012LID = 1318; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBF0000000\\012LID = 1319; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AF_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAF0000000\\012LID = 1320; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AN_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAN0000000\\012LID = 1321; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_DA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameDA0000000\\012LID = 1322; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_CA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameCA0000000\\012LID = 1323; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_BA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameBA0000000\\012LID = 1324; Local Granule ID = MISR_AM1_GRP_ELLIPSOID_GM_P155_O028745_AA_F03_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MI1B2E#00305142005054844AssociatedSensorShortNameAA0000000\\012LID = 1325; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDF0000000\\012LID = 1326; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCF0000000\\012LID = 1327; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBF0000000\\012LID = 1328; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AF_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAF0000000\\012LID = 1329; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AN_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAN0000000\\012LID = 1330; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_DA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameDA0000000\\012LID = 1331; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_CA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameCA0000000\\012LID = 1332; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_BA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameBA0000000\\012LID = 1333; Local Granule ID = MISR_AM1_GRP_RCCM_GM_P155_O028745_AA_F04_0024.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIRCCM#00405142005054844AssociatedSensorShortNameAA0000000\\012LID = 1334; Local Granule ID = MISR_AM1_GP_GMP_P155_O028745_F03_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIB2GEOP#002051420050548440000000\\012LID = 1340; Local Granule ID = MISR_AM1_TASC_MAY_F01_01.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANTASC#00205012005012142000.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_T032_F02_0010.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIANCARP#00203212005012820000.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_P155_O028745_F07_0013.hdf\\012 Input Path = /usr/ecs/OPS/CUSTOM/pdps/l0spg10/data/DpPrRm/l0spg10_disk/MIL2TCST#002051420050548440000000\\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 along-track (pixels)\\0126 ! target_patch_cross \\012 ! target patch size used in height retrievals, 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\\012ld 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\\0121 ! water_algorithm_type\\012 ! Algorithm to use for aerosol retrievals over water. \\012 ! 1 = da\\004"
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