Abstract
Estimating forest canopy height from large-footprint satellite LiDAR waveforms is challenging given the complex interaction between LiDAR waveforms, terrain, and vegetation, especially in dense tropical and equatorial forests. In this study, canopy height in French Guiana was estimated using multiple linear regression models and the Random Forest technique (RF). This analysis was either based on LiDAR waveform metrics extracted from the GLAS (Geoscience Laser Altimeter System) spaceborne LiDAR data and terrain information derived from the SRTM (Shuttle Radar Topography Mission) DEM (Digital Elevation Model) or on Principal Component Analysis (PCA) of GLAS waveforms. Results show that the best statistical model for estimating forest height based on waveform metrics and digital elevation data is a linear regression of waveform extent, trailing edge extent, and terrain index (RMSE of 3.7 m). For the PCA based models, better canopy height estimation results were observed using a regression model that incorporated both the first 13 principal components (PCs) and the waveform extent (RMSE = 3.8 m). Random Forest regressions revealed that the best configuration for canopy height estimation used all the following metrics: waveform extent, leading edge, trailing edge, and terrain index (RMSE = 3.4 m). Waveform extent was the variable that best explained canopy height, with an importance factor almost three times higher than those for the other three metrics (leading edge, trailing edge, and terrain index). Furthermore, the Random Forest regression incorporating the first 13 PCs and the waveform extent had a slightly-improved canopy height estimation in comparison to the linear model, with an RMSE of 3.6 m. In conclusion, multiple linear regressions and RF regressions provided canopy height estimations with similar precision using either LiDAR metrics or PCs. However, a regression model (linear regression or RF) based on the PCA of waveform samples with waveform extent information is an interesting alternative for canopy height estimation as it does not require several metrics that are difficult to derive from GLAS waveforms in dense forests, such as those in French Guiana.
Highlights
Standing aboveground biomass (AGB) plays a crucial role in the global carbon cycle and is an indispensable factor in environmental and climate modeling, for understanding the carbon cycle and for mitigating the effects of global warming via conservation of carbon sinks
The comparison between the canopy height estimates from Geoscience Laser Altimeter System (GLAS) waveforms using the direct method and the canopy height estimates from the LiDAR Dataset (LD) dataset showed a high root mean square error (RMSE) of 7.9 m for the estimation of the GLAS canopy height and a low R2 of 0.50 (Figure 6a)
The performance of the most frequently used linear regression models for canopy height estimation, which use metrics extracted from GLAS waveforms, was first evaluated
Summary
Standing aboveground biomass (AGB) plays a crucial role in the global carbon cycle and is an indispensable factor in environmental and climate modeling, for understanding the carbon cycle and for mitigating the effects of global warming via conservation of carbon sinks. The estimation of the canopy height using the direct method is the difference between the waveform signal start (canopy top) (Hb) and the ground peak (Hg): Hmax = Hb − Hg (2). Multiple Regression Models Using GLAS and DEM Metrics Over sloping areas, both the ground and vegetation peaks are broader and lower in intensity (e.g., [25,26]). Over sloped terrain, waveform extent will increase with the terrain slope and the footprint size [54] This increase will lead to an earlier detection of the signal start and this will lead to an overestimation of the canopy height [55]
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