Abstract
Precise accounting of carbon stocks and fluxes in tropical vegetation using remote sensing approaches remains a challenging exercise, as both signal saturation and ground sampling limitations contribute to inaccurate extrapolations. Airborne LiDAR Scanning (ALS) data can be used as an intermediate level to radically increase sampling and enhance model calibration. Here we tested the potential of using ALS data for upscaling vegetation aboveground biomass (AGB) from field plots to a forest-savanna transitional landscape in the Guineo–Congolian region in Cameroon, using either a design-based approach or a model-based approach leveraging multispectral satellite imagery. Two sets of reference data were used: (1) AGB values collected from 62 0.16-ha plots distributed both in forests and savannas; and (2) an AGB map generated form ALS data. In the model-based approach, we trained Random Forest models using predictors from recent sensors of varying spectral and spatial resolutions (Spot 6/7, Landsat 8, and Sentinel 2), along with biophysical predictors derived after pre-processing into the Overland processing chain, following a forward variable selection procedure with a spatial 4-folds cross validation. The models calibrated with field plots lead to a systematic overestimation in AGB density estimates and a root mean squared prediction error (RMSPE) of up to 65 Mg.ha−1 (90%), whereas calibration with ALS lead to low bias and a drop of ~30% in RMSPE (down to 43 Mg.ha−1, 58%) with little effect of the satellite sensor used. Decomposing bias along the AGB density range, we show that multispectral images can (in some specific cases) be used for unbiased prediction at landscape scale on the basis of ALS-calibrated statistical models. However, our results also confirm that, whatever the spectral indices used and attention paid to sensor quality and pre-processing, the signal is not sufficient to warrant accurate pixelwise predictions, because of large relative RMSPE, especially above (200–250 t/ha). The design-based approach, for which average AGB density values were attributed to mapped land cover classes, proved to be a simple and reliable alternative (for landscape to region level estimations), when trained with dense ALS samples.
Highlights
The vegetation in tropical Africa plays a major role in the global carbon cycle [1,2,3,4], providing valuable ecosystem services, storing vast amounts of carbon, and serving as a reservoir for climate mitigation [5]
To predict vegetation aboveground biomass (AGB) density from the Light Detection And Ranging (LiDAR) canopy height model, we evaluated the predictive power of a set of models using a leave-one-out cross-validation (LOO-CV) procedure
In model-based approaches, the variables selected varied depending on the training data and satellite sensor used for model calibration
Summary
The vegetation in tropical Africa plays a major role in the global carbon cycle [1,2,3,4], providing valuable ecosystem services, storing vast amounts of carbon, and serving as a reservoir for climate mitigation [5]. If we focus on high resolution multispectral (MS) imagery, such as Spot 6-7, Landsat 8, or Sentinel 2, a range of spatial and spectral resolutions is available, with potential to improve signal sensitivity to AGB. The Landsat 8 sensor provides six spectral bands with a spatial resolution of 30 m. Sentinel 2 offers ten spectral bands at refined 10 m spatial resolution. It is not clear which satellite data (between broad spectral bands and relatively high spatial resolution, i.e., Spot 6-7, or narrower, more numerous spectral bands and lower spatial resolution, i.e., Landsat 8 and Sentinel 2) provides the best solution for upscaling AGB from field data
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
