Title :
Remote sensing of forested environments: The effects of a radiometrically porous and structurally complex surface
Author :
Niemann, K.O. ; Goodenough, D.G. ; Loos, R. ; Quinn, G. ; Visintini, F.
Author_Institution :
Dept. of Geogr., Univ. of Victoria, Victoria, TX, USA
Abstract :
This study used foliar chemistry samples as calibration data to address the use of high spatial and spectral resolution hyperspectral and LiDAR data to model and predict foliar chlorophyll. We used linear multiple regression models to derive three relationships: total plot reflectance only, total plot integrated with LiDAR structure, and top of canopy reflectance. Results of the modeling suggest that nonfoliar reflectors degrade the results of the modeling and that the use of LiDAR-defined structural descriptors do little to help resolve this. The top of the canopy with the highest S/N yielded the best results. Preliminary analysis of LiDAR-related canopy structure yields some clues into the relationships with reflectance.
Keywords :
geophysical techniques; optical radar; regression analysis; remote sensing; remote sensing by radar; LiDAR data; LiDAR-defined structural descriptors; calibration data; canopy reflectance; foliar chemistry; foliar chlorophyll; forested environments; linear multiple regression models; nonfoliar reflectors; radiometrically porous complex surface; remote sensing; spectral resolution hyperspectral; structurally complex surface; Data models; Hyperspectral imaging; Laser radar; Reflectivity; Spatial resolution; LiDAR; chlorophyll; forest canopies; hyperspectral;
Conference_Titel :
Hyperspectral Image and Signal Processing: Evolution in Remote Sensing (WHISPERS), 2011 3rd Workshop on
Conference_Location :
Lisbon
Print_ISBN :
978-1-4577-2202-8
DOI :
10.1109/WHISPERS.2011.6080964
