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This project aims to create a globally representative dataset of surface reflectance, crucial for Earth Observation System products. Through theoretical basis and accurate modeling of gaseous absorption, it offers various products like BRF, Albedo, and applications including calibration analysis. The study methodically compares MODIS and MISR data, highlighting band gain differences and the impact of clouds.
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ANALYSIS OF MODIS - MISR CROSS-CALIBRATION A. Lyapustin, Y. Wang (UMBC), J. Xiong, R. Wolfe (GSFC), R. Kahn, C. Bruegge (JPL), K. Thome (UA), A. Ignatov (NOAA), S. Platnick (GSFC)
AERONET-based Surface Reflectance Validation Network (ASRVN) A. Lyapustin, Y. Wang (GEST UMBC/NASA GSFC), B. Holben, J. Privette (GSFC) • Goal – development of globally representative dataset of surface reflectance • Surface BRF and albedo are important EOS products, not yet validated globally. • Knowledge of SR is required by CM, cloud properties, and aerosol algorithms. • THEORETICAL BASIS • 3D Radiative Transfer(Lyapustin & Knyazikhin, Appl. Opt., 2001; 2002) • variable anisotropic surface; • arbitrary spatial resolution; • semi-analytical, accurate and fast due to parameterizations. • Accurate Modeling of Gaseous Absorption • Inversion with MRPVMISR and LSRTMODIS BRF Models • PRODUCTS • BRF, Albedo (spectral & SW broadband) • Surface Radiative Fluxes, PAR • Spectral Regression Coefficients (2.1 mBlue, Red) • APPLICATIONS • Validation of BRF & Albedo over Heterogeneous Surfaces • Calibration Analysis • Vicarious calibration • Cross-calibration of different sensors • Detection of calibration trend based on a time series of surface reflectance (climate quality). MISR MODIS ETM+ VIIRS
Cross-Calibration Analysis Comparison of MISR (top) and MODIS TERRA (bottom) ASRVN albedo over Mongu, Zambia
MODIS vs MISR Albedo – cont.(GSFC, USA) Artifacts of measurements Cloudy pixels
Band-pass functions of MISR (red) and MODIS land (blue) spectral channels Simulation Model: • SHARM_IPC_Mie code: • arbitrary band-pass function (MISR; MODIS; VIIRS; ETM+); • absorption of 7 major atmospheric gases (H2O, CO2, O3, CH4, NO2, CO, N2O): LBL absorption is modeled using HITRAN-2000 database and Voigt profile, continuum absorption model of AER (Clough et al.); • atmospheric profiles of Standard Models, solar irradiance model of Kurucz (MODTRAN3.0); • spectral resolution 0.01 – 1 cm-1; • full multiple scattering RT (code SHARM) with exactly calculated single scattering, Delta-M method for clouds; • Aerosol (Mie) model: • bi-modal log-normal size distribution (urban-industrial, biomass burning, dust/maritime models from Dubovik et al., 2002). • Surface models: • spectral albedo from ASTER and USGS spectral libraries; • Water cloud models: • log-normal size distribution, r=6, 10, 15, 20 m, =0.1 m; c=3.7 – 130.
rc 6 10 15 20 All AB 0.993 0.988 0.982 0.978 0.989 AR 1.038 1.044 1.045 1.046 1.041 Hc (1-5km, 0.4 cm RH) RH (0.4-2-5 cm, Hc=2 km) AB 0.980-0.987 - AG - - AR 1.036-1.039 1.042-1.046-1.061 ANir - 1.002-1.008-1.017 Simulated Regression of TOA Reflectance for Water Clouds Table 1. Dependence of slope on droplet size. Simulations were done with Hc=2km, RH=2cm, 1976 US Standard Atmospheric Profile. Table 2. Effect of cloud top height and column water vapor on the slope of regression.
Summary Table 3. Summary of regression coefficients Conclusions • We developed two independent methods to evaluate calibration bias between MODIS TERRA and MISR: • The first one derives bias as a difference between observed and theoretical regression coefficients for the TOA reflectance. • The second one evaluates bias based on statistical matching of the ASRVN albedo products from MODIS and from MISR over a large number of AERONET sites. The estimates from both methods agree well, except in the red band, where the albedo matching technique predicts about twice as high difference. • Conclusions for the first method: • Clouds prove to be a reliable stable target for the cross-calibration analysis. • Comparison of MODIS-MISR regression lines obtained from measurements and from simulations allows to evaluate the difference in the gain coefficient. • Our analysis suggests the following band gain difference: Blue – 5.8%, Green – 3.1%, Red – 1.2%.