Skip to main content
OSTI.GOVU.S. Department of Energy Office of Scientific and Technical Information
U.S. Department of Energy
Office of Scientific and Technical Information
 

The dependence of synthetic aperture radar backscatter on forest structure and biomass: Potential application for global carbon models

Thesis/Dissertation ·
OSTI ID:5298096
The NASA airborne P-band (0.438 GHz), L-band (1.25 GHz), and C-band (5.3 GHz) quadpol. SAR system was used to collect data in tropical broadleaf evergreen forests on the Island of Hawaii.l The SAR data were regressed against biomass measurements made in the field and the response curves for the tropical forests were compared to those made for coniferous forests in North America and Europe using the same SAR instrument and imaging angles (40[degrees]-50[degrees]). Results indicated that the response curves for the tropical forests and the coniferous forests were similar and that the radar signals were saturating at relatively low biomass levels. Biomass saturation points were determined at [approx]100 tons/ha for P-band, [approx]40 tons/ha for L-band, and [approx]20 tons/has for C-band (HH, VV, and HV polarization). The possible existence of a universal saturation point for the SAR response to forest biomass distinctly limits the usefulness of P-, L-, and C-band SAR for global biomass mapping. A small percentage of the world's vegetated systems falls below the highest estimated saturation level. Approximately 46% of the world's vegetated surface area containing 82% of the estimated total store of biomass lies above the saturation limit of the current radar systems (>100 tons/ha for P-band). While 54% of the Earth's vegetated surfaces area is below the saturation level for P-band, this class contains only an estimated 18% of total biomass represented by terrestrial vegetation. Theoretical modeling indicated the primary forest canopy structural factor influencing SAR backscatter was the surface area to volume ratio (SA/V) of the branches. This proved true for both broadleaf evergreens and conifers. As a forest stand matures, the form of the phytomass coalesces into fewer larger components and the calculated SA/V declines as biomass increases. As the SA/V declines the backscatter trends to increase since the radar has larger components from which reflections can occur.
Research Organization:
Stanford Univ., CA (United States)
OSTI ID:
5298096
Country of Publication:
United States
Language:
English

Similar Records

Dependence of radar backscatter on coniferous forest biomass
Journal Article · Sat Feb 29 23:00:00 EST 1992 · IEEE Transactions on Geoscience and Remote Sensing (Institute of Electrical and Electronics Engineers); (United States) · OSTI ID:5119514
Relating forest biomass to SAR data
Journal Article · Sat Feb 29 23:00:00 EST 1992 · IEEE Transactions on Geoscience and Remote Sensing (Institute of Electrical and Electronics Engineers); (United States) · OSTI ID:5044916

Related Subjects

09 BIOMASS FUELS
090700 -- Biomass Fuels-- Resources-- (1990-)
54 ENVIRONMENTAL SCIENCES
540210* -- Environment
Terrestrial-- Basic Studies-- (1990-)
BIOMASS
CARBON CYCLE
COMPARATIVE EVALUATIONS
CONIFERS
ENERGY SOURCES
EVALUATION
FORESTS
GLOBAL ASPECTS
MATHEMATICAL MODELS
MEASURING INSTRUMENTS
PINOPHYTA
PLANTS
RADAR
RANGE FINDERS
RENEWABLE ENERGY SOURCES
SYNTHETIC-APERTURE RADAR
TROPICAL REGIONS