Title :
Improved accuracy for interferometric radar images using polarimetric radar and laser altimetry data
Author :
Slatton, K. Clint ; Crawford, Melba M. ; Evans, Brian L.
Author_Institution :
Center for Space Res., Texas Univ., Austin, TX, USA
Abstract :
The ability to measure land surface topography over large areas to assess natural hazard threats posed by seismic and flooding events is a critical international need. Interferometric synthetic aperture radar (INSAR) has been used to map topography; however, accuracies are limited because observations are not measurements of true surface topography over vegetated areas. Instead, the measurements, which depend on the sensor and the vegetation, represent some height above the true surface. We develop a two-step correction for the INSAR imagery to account for penetration into the vegetation. The INSAR imagery is first adaptively filtered to reduce random measurement noise. We then combine the INSAR with polarimetric radar and laser altimetry data to account for the vegetation contribution to the topographic heights
Keywords :
adaptive filters; geophysical signal processing; height measurement; interferometry; radar imaging; radar polarimetry; synthetic aperture radar; vegetation mapping; INSAR; adaptive filtering; flooding events; interferometric radar images; interferometric synthetic aperture radar; land surface topography measurement; laser altimetry; natural hazard threats; polarimetric radar; random measurement noise; seismic events; topographic heights; two-step correction; vegetated areas; vegetation penetration; Area measurement; Floods; Hazards; Land surface; Laser radar; Radar imaging; Seismic measurements; Surface topography; Synthetic aperture radar interferometry; Vegetation mapping;
Conference_Titel :
Image Analysis and Interpretation, 2000. Proceedings. 4th IEEE Southwest Symposium
Conference_Location :
Austin, TX
Print_ISBN :
0-7695-0595-3
DOI :
10.1109/IAI.2000.839591
