BI-DIRECTIONAL REFLECTANCE MODELING AND IT’S INVERSION TO RETRIEVE WHEAT BIOPHYSICAL PARAMETERS
KrishiKosh
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Title |
BI-DIRECTIONAL REFLECTANCE MODELING AND IT’S INVERSION TO RETRIEVE WHEAT BIOPHYSICAL PARAMETERS
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Creator |
DEBASISH CHAKRABORTY
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Contributor |
V.K. Sehgal
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Subject |
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Description |
T-8411
Accurate and repetitive estimation of vegetation biophysical parameters at regional scales are required for a large number of ecological, meteorological and agricultural applications. Anisotropic reflectance behaviour in remote sensing observations provides more information than nadir reflectance for distinguishing features and deriving their biophysical information at regional scales. Canopy radiative transfer models are based on explicitly defined relation between biophysical variables and canopy anisotropic reflectance which can be inverted to derive canopy parameters. This study describes (a) the measurements and analysis of bi- directional reflectance anisotropy of wheat, (b) rigorous validation of canopy radiative transfer model PROSAIL5B, and (c) retrieval of wheat biophysical variables of leaf chlorophyll (Cab), LAI, canopy chlorophyll (CCC), and leaf wetness (Cw) by inversion of PROSAIL using different inversion approaches. The study reconfirms the strong and consistent anisotropic patterns of wheat reflectance in VIS and NIR regions in response to change in sun-target-sensor geometry and the magnitude was highest in the principal plane. The study found that this anisotropic pattern extends equally in SWIR wavelength region also. The PROSAIL model simulated spectra was in good agreement with the observed spectra for all the view zenith and azimuth angle combinations used in the experiment. The model simulations also showed very good match in the principal plane, the region of highest anisotropy, except in the VIS band where little underestimation was found in the back scattering direction at higher view zenith angles.The model performed best in the NIR region followed by SWIR and maximum relative error was observed for VIS region. Over the whole optical region, model simulations showed an average error of 27 percent and this average error was higher (~33%) in nadir view position than in off-nadir view position. The inversion approaches implemented were: a look up table with best solution (LUT-I), a look up table with best 10% solutions (LUT-II) and an artificial neural network (ANN) approach. All the approaches could estimate the biophysical variables by capturing variability in their observed values, though accuracy of estimation varied among three parameters. Approach LUT-II outperformed other two approaches indicating that a set of best 10% solutions is a better strategy while ANN was worst performer. In most of the cases, the parameters were underestimated signifying the limitation in PROSAIL model to accurately simulate the full range of crop reflectance. In all the inversion approaches the general order of estimation accuracy was LAI > Cab > CCC > Cw. The range of Cw was very narrow and none of the approaches could estimate variations in it. Performance of inversion was comparable for IRS LISS-III and LandSat ETM+ broadband reflectances in optical region. The findings of this study may help in generating operational crop biophysical products using IRS LISS-III sensor by space agencies across the world. |
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Date |
2016-11-02T15:34:40Z
2016-11-02T15:34:40Z 2011 |
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Type |
Thesis
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Identifier |
http://krishikosh.egranth.ac.in/handle/1/83437
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Format |
application/pdf
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Publisher |
IARI, DIVISION OF AGRICULTURAL PHYSICS
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