Evaluation of Narrowband and Broadband Vegetation Indeces for Determining Optimal Hyperspectral Wavebands for Agricultural Crop Characterization
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Prasad Thenkabail, Ronald B Smith, Eddy De Pauw. (1/6/2002). Evaluation of Narrowband and Broadband Vegetation Indeces for Determining Optimal Hyperspectral Wavebands for Agricultural Crop Characterization. Photogrammetric Engineering and Remote Sensing, 68 (6), pp. 607-621.
Abstract
The main goal of the study was to determine optimal waveband
centers and widths required to best estimate agricultural crop
characteristics. The hyperspectral narrowband data was acquired over 395 to 1020 nanometers using a 1.43-nanometerwide, 430 bands, hand-held spectroradiometer. Broadband
data were derived using a Landsat-5 Thematic Mapper image
acquired to correspond with field spectroradiometer and
ground-truth measurements. Spectral and biophysical data
were obtained from 196 sample locations, including farms and
rangelands. Six representative crops grown during the main
cropping season were selected: barley, wheat, lentil, cumin,
chickpea, and vetch. Biophysical variables consisted of leaf
area index, wet biomass, dry biomass, plant height, plant
nitrogen, and canopy cover.
Narrowband and broadband vegetation indices were computed and their relationship with quantitative crop characteristics were established and compared. The simple narrowband two-band vegetation indices [TBVI) and the optimum
multiple-band vegetation indices [OMBVI) models provided the
best results. The narrowband TBW and OMBvI models are
compared with six other categories of narrow and broadband
indices. Compared to the best broadband TM indices, TBW
explained up to 24 percent greater variability and OMBVI
explained up to 27 percent greater variability in estimating
different crop variables. A Predominant proportion of crop
characteristics are best estimated using data from four narrowbands, in order of importance, centered around 675
nanometers [red absorption maxima), 905 nm (near-infrared
reflection peak), 720 nm [mid portion of the red-edge), and
550 nm [green reflectance maxima). The study determined 12
spectral bands and their bandwidths [Table 5) that provide
optimal agricultural crop characteristics in the visible and
near-infrared portion of the spectrum.