Remote Sensing the Spatial Distribution of Crop Residues

doi:10.2134/agronj2003.0291

Remote Sensing

Remote Sensing the Spatial Distribution of Crop Residues

C. S. T. Daughtry^*, E. R. Hunt, Jr., P. C. Doraiswamy and J. E. McMurtrey, III

USDA-ARS, Hydrol. and Remote Sens. Lab., Bldg. 007, Rm. 104, 10300 Baltimore Ave., Beltsville, MD 20705-2350 USA

^* Corresponding author (cdaughtry{at}hydrolab.arsusda.gov)

Received for publication November 26, 2003. Management of plant litter or crop residues in agriculturalfields is an important consideration for reducing soil erosionand increasing soil organic C. Current methods of quantifyingcrop residue cover are inadequate for characterizing the spatialvariability of residue cover within fields and across largeregions. Our objectives were to evaluate several spectral indicesfor measuring crop residue cover using ground-based and airbornehyperspectral data and to categorize soil tillage intensityin agricultural fields based on crop residue cover. Reflectancespectra of mixtures of crop residues, green vegetation, andsoil were acquired over the 400- to 2500-nm wavelength region.High-altitude AVIRIS (Airborne Visible Infrared Imaging Spectrometer)data were also acquired near Beltsville, MD, in May 2000. Broadabsorption features near 2100 and 2300 nm in the reflectancespectra of crop residues were associated with cellulose andlignin. These features were not evident in the spectra of greenvegetation and soils. Crop residue cover was linearly relatedto the cellulose absorption index, which was defined as therelative depth of the 2100-nm absorption feature. Other spectralindices for crop residue were calculated and evaluated. Thebest spectral indices were based on relatively narrow (10–50nm) bands in the 2000- to 2400-nm region, were linearly relatedto crop residue cover, and correctly identified tillage intensityclasses in >90% of test agricultural fields. Regional surveysof soil management practices that affect soil conservation andsoil C dynamics may be feasible using advanced multispectralor hyperspectral imaging systems.

Abbreviations: ASTER, Advanced Spaceborne Thermal Emission and Reflection • AVIRIS, Airborne Visible Infrared Imaging Spectrometer • CAI, Cellulose Absorption Index • CT, conservation tillage • LCA, Lignin Cellulose Absorption (index) • NDI, Normalized Difference Index • NDSVI, Normalized Differential Senescent Vegetation Index • NDTI, Normalized Difference Tillage Index • NDVI, Normalized Difference Vegetation Index • OSAVI, Optimized Soil-Adjusted Vegetation Index • RT, reduced tillage • TM, Thematic Mapper • VARI, Visible Atmospherically Resistant Index • VI_green, green vegetation index

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				B. K. Gelder, A. L. Kaleita, and R. M. Cruse Estimating Mean Field Residue Cover on Midwestern Soils Using Satellite Imagery Agron. J., May 8, 2009; 101(3): 635 - 643. [Abstract] [Full Text] [PDF]

				D.G. Sullivan, T.C. Strickland, and M.H. Masters Satellite mapping of conservation tillage adoption in the Little River experimental watershed, Georgia Journal of Soil and Water Conservation, May 1, 2008; 63(3): 112 - 119. [Abstract] [PDF]

				D.G. Sullivan, D. Lee, J. Beasley, S. Brown, and E.J. Williams Evaluating a crop residue cover index for determining tillage regime in a cotton-corn-peanut rotation Journal of Soil and Water Conservation, January 1, 2008; 63(1): 28 - 36. [Abstract] [PDF]

				D.G. Sullivan, J.N. Shaw, A. Price, and E. van Santen Spectral Reflectance Properties of Winter Cover Crops in the Southeastern Coastal Plain Agron. J., November 6, 2007; 99(6): 1587 - 1596. [Abstract] [Full Text] [PDF]

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