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Mapping Drought and Evapotranspiration at High Resolution using Landsat/GOES Thermal Imagery

Mapping Drought and Evapotranspiration at High Resolution using Landsat/GOES Thermal Imagery. M.C. Anderson, W.P. Kustas USDA-ARS, Hydrology and Remote Sensing Laboratory. J.M. Norman U Wisconsin-Madison. C.M.U. Neale Utah State University. OBJECTIVES.

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Mapping Drought and Evapotranspiration at High Resolution using Landsat/GOES Thermal Imagery

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  1. Mapping Drought and Evapotranspiration at High Resolution using Landsat/GOES Thermal Imagery M.C. Anderson, W.P. Kustas USDA-ARS, Hydrology and Remote Sensing Laboratory J.M. Norman U Wisconsin-Madison C.M.U. Neale Utah State University

  2. OBJECTIVES • Develop multi-satellite thermal ET/drought product at 30m – 10km resolution • GOES: Hourly continental coverage at 5-10km resolution • Landsat: Periodic targeted disaggregation to 30-120m resolution 2) Develop technique for sharpening thermal band imagery to shortwave band resolution • i.e., sharpen 60/120m (L7/L5) resolution thermal images to 30m

  3. !! IMPENDING THERMAL DATA GAP Land Surface Temperature and Emissivity Earth System Data Record (LSTE-ESDR) Table from S. Hook

  4. OBJECTIVE 1 Map ET and moisture stress (drought) using thermal infrared (TIR) and vegetation index (VI) remote sensing data. Varying soil moisture conditions yield distinctive thermal signatures: • depletion of water from the soil surface layer causes the soil component of the scene to heat up rapidly. • moisture deficiencies in the root zone lead to vegetation stress and elevated canopy temperatures

  5. ? Operational Drought Monitoring Palmer Drought Index Antecedent precipitation Vegetation Health Index NDVI-NDVImin VCI = NDVImax-NDVImin Tmax-T TCI = Tmax-Tmin VHI = aVCI + (1-a)TCI Evaporative Stress Index ESI = 1 – AET/PET

  6. SURFACE TEMPERATURE EVAPOTRANSPIRATION ALEXI (GOES Sounder) Continental ALEXI (GOES Imager) Regional DisALEXI (Landsat) Watershed DisALEXI (USU aircraft) CORN Field scale Latent Heat (Wm-2) Temperature (C) SOY

  7. 2002 2003 2004 APR Dry MAY JUN DESI JUL AUG Wet SEP Monthly anomalies

  8. 2003 DESI DZ 2002 DESI DZ APR MAY JUN JUL AUG SEP

  9. 2004 DESI DZ 2002 DESI DZ APR MAY JUN JUL AUG SEP

  10. Landsat Multi-scale Drought Monitoring DESI GOES

  11. ESI validation sites Fort Peck Black Hills SMEX02/05 BARC Bondville Bushland SGP97 Walker Branch SMEX04 Sevilleta Goodwin Creek Audubon Gainesville Everglades

  12. TRAD NDVI OBJECTIVE 2 Develop thermal band sharpening technique Idabel, OK NDVI (30-m) TRAD (60-m)

  13. Sharpened Thermal Sharpening Idabel, OK Unsharpened

  14. Latent heat flux with thermal sharpening Unsharpened Sharpened

  15. Simulated MODIS Sharpening (Ames, IA) Unsharpened (1 km) Reference (250 m) Sharpened (250 m)

  16. Simulated MODIS/TM Sharpening (Bushland, TX) Unsharpened (1 km) Reference (250 m) Sharpened (250 m) Reference (120 m) Sharpened (120 m) Reference (60 m) Sharpened (60 m)

  17. Sharpened (30m) Reference (30m) Fraction vegetation cover Temperature (oC) Fraction vegetation cover Anomalies associated with sub-pixel irrigation Unsharpened

  18. Thermal sharpening validation sites WA WY IA UT IL CA OK NM

  19. The importance of Landsat-resolution thermal data 240m 960m 120m 60m Evapotranspiration (W m-2)

  20. The importance of Landsat-resolution thermal data LE (Wm-2) TR (O K) 60 m 120 m 960 m (~ETM+) (~TM) (~MODIS) 29 July 2004 – Southern Arizona (San Pedro River Basin)

  21. manderson@hydrolab.arsusda.gov

  22. Atmosphere-Land Exchange Inverse Model (ALEXI) Regional scale DTRAD - GOES fc - AVHRR, MODIS Landscape scale TRAD - TM, ASTER, MODIS fc - TM, ASTER, MODIS

  23. “Non-Irrigated” subset – Temperature fields uniTrad TsHARP Trad(reference) Fraction vegetation cover Temperature (oC) Fraction vegetation cover

  24. 2002 2003 2004 APR Low MAY JUN (Wm-2) EVAPOTRANSPIRATION JUL AUG High SEP

  25. ALEXI Precipitation 2002 2003 2004 Dry Wet ESI anomaly Precipitation anomaly (mm)

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