|Month Published:||MAY 20|
|Author:||Galvao, LS ; Ponzoni, FJ ; Epiphanio, JCN ; Rudorff, BFT ; Formaggio, AR|
|Book Group Author:||NA|
Solar zenith and view angle effects on the normalized difference vegetation index (NDVI) of land cover types in the Brazilian Amazon region were analysed. Airborne Hyperspectral Mapper (HYMAP) data were collected in 126 narrow bands (450-2500 nm) with a field of view (FOV) of +/-30degrees from nadir. Data collection was performed initially in two flight lines with solar zenith angles of 29degrees and 53degrees. In a third flight line, view angles were up to +60degrees from nadir by airplane banking. Surface reflectance spectra representative of major land cover types were selected, and principal component analysis was applied to indicate their spectral similarity relationships in response to solar zenith angle variations. Reflectance and NDVI differences between pairs of land cover types were plotted for a variable band positioning. Atmospheric and coupled directional effects were analysed for variations in apparent and surface reflectance values, in the depth of the major water vapour absorption bands, and in the NDVI values, as a function of view angle. The results showed that major Amazon land cover types had increased NDVI values with increase in solar zenith angle, especially exposed soil or other vegetated surface components under soil background influence. Small solar zenith angles improved the NDVI contrast between green vegetation and soil and also the land cover discrimination in all bands, except for those placed in the 750-1100 nm range. At large solar zenith angles, this spectral interval was useful to separate primary forest/old woody vegetation regrowth from most of the other surface components due to enhancement in the shade fraction associated with the arboreal covers. Small differences in NDVI values of tropical rainforest were observed between +/-25degrees from nadir. These differences became stronger with the increase in view angle from +25degrees to +60degrees in response to the additive and subtractive contributions of atmospheric scattering and absorption, respectively, and of coupled directional effects.
|Journal:||INTERNATIONAL JOURNAL OF REMOTE SENSING|
|Journal ISO:||Int. J. Remote Sens.|
|Publisher:||TAYLOR & FRANCIS LTD|
|Source:||Web of Science|