Title :
Predicting backscatter-biomass and height-biomass trends using a macroecology model
Author :
Woodhouse, Iain Hector
Author_Institution :
Edinburgh Earth Obs., Univ. of Edinburgh, UK
fDate :
4/1/2006 12:00:00 AM
Abstract :
This study describes the use of a plant structure model from the field of macroecology to make generalized predictions about backscatter-biomass and height-biomass trends from synthetic aperture radar data over forests. A theoretical relationship between canopy height and biomass density is derived. The predicted values of the height exponent are comparable with those from the remote sensing literature. A radiative transfer model parameterized by the macroecology model is also used to predict trends in P-band backscatter. The results imply that backscatter can saturate even for low-opacity canopies and decreasing basal area results in backscatter saturating at lower biomass levels. The theoretical analysis is supported by reference to a range of published results.
Keywords :
backscatter; ecology; forestry; radar theory; radiowave interferometry; remote sensing by radar; synthetic aperture radar; vegetation mapping; P-band backscatter; backscatter-biomass trend; biomass density; canopy height; forestry; height exponent; height-biomass trend; macroecology model; plant structure model; radiative transfer model; remote sensing; synthetic aperture radar; Backscatter; Biological system modeling; Biomass; Forestry; Plants (biology); Predictive models; Remote sensing; Synthetic aperture radar; Uncertainty; Vegetation; Biomass; forestry; synthetic aperture radar (SAR); vegetation;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
DOI :
10.1109/TGRS.2006.872356
