Observations of forest stand top height and mean height from interferometric SAR and LiDAR over a conifer plantation at Thetford Forest, UK

Balzter, H.; Luckman, A.; Skinner, L.; Rowland, C. ORCID: https://orcid.org/0000-0002-0459-506X; Dawson, T.. 2007 Observations of forest stand top height and mean height from interferometric SAR and LiDAR over a conifer plantation at Thetford Forest, UK. International Journal of Remote Sensing, 28 (6). 1173-1197. https://doi.org/10.1080/01431160600904998

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Abstract/Summary

Estimates of forest stand mean height using airborne LiDAR (light detection and ranging) instruments have been reported previously with accuracies comparable to traditional ground-based measurements. However, the small area covered by a LiDAR sensor in a single aircraft overpass is a significant hindrance for large-scale forest inventories. In comparison, airborne interferometric synthetic aperture radar (InSAR) systems are also able to make estimates of surface height, but the swath coverage is often far greater, typically five or ten times that of the LiDAR coverage. A set of interferometric data takes was acquired by the ESAR airborne sensor over a managed pine plantation at Thetford Forest, UK. Scattering phase centre height estimates were made from two single-pass X-band acquisitions and polarimetric repeat-pass L-band acquisitions and compared with height estimates made from a separate LiDAR acquisition. The relationship between the scattering phase centre heights and stand top heights estimated, and the accuracy of stand top height estimates estimated from InSAR and LiDAR is quantified by the root mean square error (rmse). General yield class models by the Forestry Commission (UK) were used to estimate stand top height from a GIS database used for forest management. The longer wavelength L-band radiation penetrates deeper into the canopy than the X-band, and the scattering phase centre height is affected by both forest structural parameters (canopy density, understorey, and gaps) and sensor parameters (look-angle and reduced coherence through temporal and volume decorrelation). Consequently, a simple translation of scattering phase centre height into stand top height gives noisy results for L-band, with observed rmse values between ±3.1 m in the near-range and ±6.4 m in the far-range. The X-band based top height estimates are more accurate, with rmse between ±2.9 m in the near- and ±4.1 m in the far-range, which can be further reduced by an empirical incidence angle correction. Stand top height estimates from LiDAR achieved an rmse of only ±2.0 m. The X-band scattering phase centre heights have also been related to mean stand height and are comparable with heights observed from the LiDAR sensor and field measurements. An rmse of ±2.5 m for the mean stand height estimates based on the X-band dataset was found. Finally, we briefly discuss error propagation from the use of a terrain model, here provided by the Ordnance Survey.

Item Type:	Publication - Article
Digital Object Identifier (DOI):	https://doi.org/10.1080/01431160600904998
Programmes:	CEH Programmes pre-2009 publications > Biogeochemistry
UKCEH and CEH Sections/Science Areas:	Harding (to July 2011)
ISSN:	0143-1161
NORA Subject Terms:	Ecology and Environment Electronics, Engineering and Technology
Date made live:	15 Oct 2007 15:18 +0 (UTC)
URI:	https://nora.nerc.ac.uk/id/eprint/996

Item Type:

Publication - Article

Digital Object Identifier (DOI):

https://doi.org/10.1080/01431160600904998

Programmes:

CEH Programmes pre-2009 publications > Biogeochemistry

UKCEH and CEH Sections/Science Areas:

Harding (to July 2011)

ISSN:

0143-1161

NORA Subject Terms:

Ecology and Environment
Electronics, Engineering and Technology