Uncertainty within satellite LiDAR estimations of vegetation and topography

Uncertainty within satellite LiDAR estimations of vegetation and topography

This paper demonstrates the ability to identify representative ground elevation and vegetation height estimates within the Ice, Cloud and land Elevation Satellite/Geoscience Laser Altimeter System (ICESat/GLAS) waveforms for an area of mixed vegetation and varied topography. Estimating vegetation he...

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Bibliographic Details
Published in:International journal of remote sensing Vol. 31; no. 5; pp. 1325 - 1342
Main Authors: Rosette, J. A. B., North, P. R. J., Suárez, J. C., Los, S. O.
Format: Journal Article Conference Proceeding
Language:English
Published: Abingdon Taylor & Francis 26-03-2010
Subjects:
Animal, plant and microbial ecology
Applied geophysics
Biological and medical sciences
Earth sciences
Earth, ocean, space
Exact sciences and technology
Fundamental and applied biological sciences. Psychology
General aspects. Techniques
Internal geophysics
Lidar
Remote sensing
Satellites
Teledetection and vegetation maps
Topography
Uncertainty
Vegetation
laser methods
data
springs
vegetation
ice
clouds
slopes
System
Slope
Field
Ground surface
Height
uncertainties
Ability
satellites
Estimation
topography
Representation
utilization
optical properties
signals
Laser
Lidar
waveforms
Canopy(vegetation)
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Summary:This paper demonstrates the ability to identify representative ground elevation and vegetation height estimates within the Ice, Cloud and land Elevation Satellite/Geoscience Laser Altimeter System (ICESat/GLAS) waveforms for an area of mixed vegetation and varied topography. Estimating vegetation height within large-footprint Light Detection and Ranging (LiDAR) waveforms relies on the ability to estimate the uppermost canopy surface (signal beginning) and an elevation representing the ground surface, both of which are influenced by vegetation properties and topographic slope. We examined sources of uncertainty for vegetation height estimation from ICESat/GLAS data using airborne LiDAR data, field measurements and the FLIGHT radiative transfer model. In comparison with an independent 10-m resolution digital terrain model (DTM), a method using Gaussian decomposition of the satellite waveform produced a mean bias of −0.10 m when estimating ground elevation. A second method of estimating vegetation height using waveform extent and a terrain index effectively removed slope as an error source but produced a greater ground surface offset (−0.83 m). The two methods of estimating vegetation height compared well with airborne LiDAR estimates (correlation coefficient (R 2 ) = 0.68, root mean square error (RMSE) = 4.4 m and R 2  = 0.61, RMSE = 4.9 m, respectively). However, the complex interplay of the structural and optical properties of the intercepted vegetation and slope requires further understanding. A tool such as FLIGHT provides a useful means to explore the sensitivity of the waveform to both vegetation properties and topographic slope.
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ISSN:0143-1161
1366-5901
DOI:10.1080/01431160903380631