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Limitations of high resolution satellite stereo imagery for estimating canopy height in Australian t

March 2019,ElsevierPublication, Volume 75, Pages 83-95



Highlights

· Very High Resolution (VHR) stereo satellites were assessed for estimating vegetation canopy height in Australian savannas.

· Semi-global dense matching (SGM) image-based techniques produced poor results (8–9% tree detection rate).

· The highest tree detection rates were achieved by using the near-infrared (NIR) band.

· Poor image matching results likely stem from the clumping crown structure and erectophile foliage of the dominant Eucalyptspp.

· Cross-satellite (mixed) models couldn’t improve the quality of extracted Canopy Height Models (CHM).

Abstract

Obtaining reliable measures of tree canopy height across large areas is a central element of forest inventory and carbon accounting. Recent years have seen an increased emphasis on the use of active sensors like Radar and airborne LiDAR (light detection and scanning) systems to estimate various 3D characteristics of canopy and crown structure that can be used as predictors of biomass. However, airborne LiDAR data are expensive to acquire, and not often readily available across large remote landscapes. In this study, we evaluated the potential of stereo imagery from commercially available Very High Resolution (VHR) satellites as an alternative for estimating canopy height variables in Australian tropical savannas, using a Semi-Global dense Matching (SGM) image-based technique. We assessed and compared the completeness and vertical accuracy of extracted canopy height models (CHMs) from GeoEye 1 and WorldView 1 VHR satellite stereo pairs and summarized the factors influencing image matching effectiveness and quality.

Our results showed that stereo dense matching using the SGM technique severely underestimates tree presence and canopy height. The highest tree detection rates were achieved by using the near-infrared (NIR) band of GE1 (8–9%). WV1-GE1 cross-satellite (mixed) models did not improve the quality of extracted canopy heights. We consider these poor detection rates and height retrievals to result from: i) the clumping crown structure of the dominant Eucalyptspp.; ii) their vertically oriented leaves (affecting the bidirectional reflectance distribution function); iii) image band radiometry and iv) wind induced crown movement affecting stereo-pair point matching. Our detailed analyses suggest that current commercially available VHR satellite data (0.5 m resolution) are not well suited to estimating canopy height variables, and therefore above ground biomass (AGB), in Eucalyptus dominated north Australian tropical savanna woodlands.

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