BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Assessment of Albedo Derived from MODIS at ChEAS - Park Falls ChEAS 2006 Meeting: June 5 - June.

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BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Assessment of Albedo Derived from MODIS at ChEAS - Park Falls ChEAS 2006 Meeting: June 5 - June 6, 2006 Miguel O. Román Crystal B. Schaaf Alan H. Strahler John C. F. Hodges Jicheng Liu

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Background MCD43 Albedo: Overview and Applications Measuring Ground-Truth Albedo Calculating MODIS-Derived Albedos V005 Product Assessment at ChEAS (2005) Upscaling Methods MODIS ASCII Subsets

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Albedo of Sahara The variation across the land’s surface affects how much solar radiation is absorbed and how much is reflected back up into the overlying atmosphere. This image was produced using 1-km RGB composites over a 16-day period, from April 7-22, 2002.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu MODIS BRDF/Albedo Applications “Correction” of observations for directional effects – Nadir BRDF-Adjusted Reflectance (NBAR) standardizes reflectance to a specific view and illumination geometry—solar noon, at nadir. Global mapping of surface albedo applications: – Parameterize global climate and biogeochemical models. – Initialize numerical weather prediction and mesoscale models. – Quantify the surface background for cloud studies. Characterization of surface scattering behavior – Non-Lambertian surface BRDF effects. – Quantify the surface anisotropy. – Identification of surface changes.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Measuring Albedo Albedometer: Combines two pyranometers, one facing upward and one facing downward. The upward facing pyranometer measures global radiation (diffuse and direct solar radiation). An albedometer measuring frost flowers on young ice The downward facing pyranometer measures reflected solar radiation. Albedo can be calculated from the output data. Short-wave net radiation ( um) can also be calculated.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Actual albedo is a function of wavelength, illumination angles, atmosphere (aerosols) and surface characteristics: E irradiance (λ) = E absorb (λ) + E transmitted (λ) + E reflected (λ) where, Transmittance = E transmitted / E irradiance Absorptance = E absorb /E irradiance Albedo represents the Hemispherical Reflectance: Albedo = E reflected /E irradiance Directional hemispherical albedo reflectance and bihemis- pherical albedo under completely isotropic radiation are intrinsic characteristics of the surface. We can obtain an actual albedo as measured by an albedometer by combining these two intrinsic quantities as a function of the atmospheric optical depth and accounting for multiple scattering effects. Calculating Albedo

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Albedos are produced from MODIS-derived BRDF models. The BRDF model requires multi-date, multi-spectral, cloud-free, surface reflectances to capture anisotropy across viewing/ illumination geometry. BRDF model parameters are retrieved — the linear combination of a constant (f iso ) and two weighted (f vol, f geo ) trigonometric functions (k vol, k geo ) derived from physical models of volumetric and geometric-optical surface scattering that best fit the data: Full model inversions are used when sufficient high quality atmospherically- corrected cloud-free observations are available over a 16-day period to adequately sample the BRDF. Otherwise, lower quality magnitude inversions are performed which couple a priori knowledge of the surface anisotropy with any high quality MODIS observations that are available for a location. Calculating MODIS-Derived Albedo

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Validation: ARM-SGP Extended Facility # Time Series We make retrievals every 8 days (based on the last 16 days) to increase the possibility of obtaining high quality results. We will tap into the time sequences of measured surface albedo for the WLEF-ChEAS site and compare those with MODIS-based estimates.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Combining observations from Aqua and Terra –Increases high-quality inversions Best fit BRDF model retrieved directly from observations. –Fewer lower-quality retrievals using the back-up algorithm Back-up method relies on a priori designation of BRDF. Combined Aqua+Terra V004 reprocessing complete V005 – MCD meter product (Terra alone prior to May 2002) Combined Aqua + Terra Processing

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Shortwave White-Sky Albedo ( mm) August 5 th, 2005 ( ) Terra-onlyAqua plus Terra

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Mandatory QA ( mm) August 5 th, 2005 ( ) Terra-onlyAqua plus Terra No Data (Fill Value)White Moderate Quality – Magnitude InversionsRed Best Quality – Full BRDF-InversionsGreen

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu White Sky Albedo – True Color (RGB) August 13 th, 2005 ( ) V004 MOD43B3 (1km)V005 MCD43A3 (500m)

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Upscaling Efforts

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Upscaling Efforts Ground measurements are used to ‘‘calibrate’’ the products from high- resolution imagery, which are then aggregated to the MODIS resolutions.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu QuickBird panchromatic (0.6m) scene of Park Falls tower site (Sinusoidal Projection) Chequamegon Ecosystem-Atmosphere Study (ChEAS) QuickBird panchromatic (0.6m) scene of Park Falls tower site (UTM Projection)

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Upscaling Methods We cannot compare ground point measurements to MODIS pixel values because of the scale mismatch. Unless the surface is large and perfectly homogeneous, or a sufficient number of point measurements can be made during the satellite overpass, “point” measurements may not be sufficient to validate MODIS products if direct comparison is employed. Upscaling Efforts

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu Main Lesson: Upscaling from ground point measurements to the MODIS resolutions using high resolution remotely sensed imagery is a necessary and critical step.

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu MODIS ASCII Subsets

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu MODIS ASCII Subsets: Data Visualization

BRDF/ALBEDO GROUP Román, Schaaf, Strahler, Hodges, Liu MODIS ASCII Subsets: Data Visualization Shortwave Broadband Blue-Sky (Actual) Albedo Shortwave Broadband Black-Sky AlbedoShortwave Broadband White-Sky Albedo Percent of Pixels having Acceptable QualityGreen Every Pixel having Acceptable QualityBlue Average of Pixels in 7x7 Grid having Valid DataRed