Abstract
Mapping forest AGB (Above Ground Biomass) is of crucial importance to estimate the carbon emissions associated with tropical deforestation. This study proposes a method to overcome the saturation at high AGB values of existing AGB map (Vieilledent's AGB map) by using a map of correction factors generated from GLAS (Geoscience Laser Altimeter System) spaceborne LiDAR data. The Vieilledent's AGB map of Madagascar was established using optical images, with parameters calculated from the SRTM Digital Elevation Model, climatic variables, and field inventories. In the present study, first, GLAS LiDAR data were used to obtain a spatially distributed (GLAS footprints geolocation) estimation of AGB (GLAS AGB) covering Madagascar forested areas, with a density of 0.52 footprint/km 2. Second, the difference between the AGB from the Vieilledent's AGB map and GLAS AGB at each GLAS footprint location was calculated, and additional spatially distributed correction factors were obtained. Third, an ordinary kriging interpolation was thus performed by taking into account the spatial structure of these additional correction factors to provide a continuous correction factor map. Finally, the existing and the correction factor maps were summed to improve the Vieilledent's AGB map. The results showed that the integration of GLAS data improves the precision of Vieilledent's AGB map by approximately 7 t/ha. By integrating GLAS data, the RMSE on AGB estimates decreases from 81 t/ha (R 2 = 0.62) to 74.1 t/ha (R 2 = 0.71). Most importantly, we showed that this approach using LiDAR data avoids underestimating high biomass values (new maximum AGB of 650 t/ha compared to 550 t/ha with the first approach).
Highlights
Monitoring the carbon cycle and carbon stocks is of high importance to understand climate change
The main goal of this study is to investigate the contribution of spaceborne LiDAR data in overcoming the saturation at high Above Ground Biomass (AGB) values of existing map produced in Madagascar by Vieilledent et al [28] using optical satellite images, a Digital Elevation Model (DEM) and climatic variables
14 plots neighboring Geoscience Laser Altimeter System (GLAS) footprints at a distance of 250 m in the eastern ecoregion were used to relate the in situ AGB to all GLAS and DEM metrics (Wext_cor, Leading Edge (LE), TE, H10 through H90, slope, TI, and Roug)
Summary
Monitoring the carbon cycle and carbon stocks is of high importance to understand climate change. In tropical forests, the quantity of carbon represents 43% to 55% of Remote Sens. Mapping the AGB of tropical forests is of great importance in monitoring carbon stocks. Field inventories for AGB estimates, either by destructive (cutting and weighing the tree) or non-destructive methods (by means of allometric equations), provide good estimates. These methods are not operational because they involve a great deal of labor and time and allow AGB estimates only at a local scale. A forest cannot be mapped using field inventories, the importance of remote sensing technology that facilitates the mapping of AGB
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