Abstract
Forest Aboveground Biomass (AGB) is a key parameter for assessing forest productivity and global carbon content. In previous studies, AGB has been estimated using various prediction methods and types of remote sensing data. Increasingly, there is a trend towards integrating various data sources such as Light Detection and Ranging (LiDAR) and optical data. In this study, we constructed and compared the accuracies of five models for estimating AGB of forests in the upper Heihe River Basin in Northwest China. The five models were constructed using field and remotely-sensed data (optical and LiDAR) and algorithms including Random Forest (RF), Support Vector Machines (SVM), Back Propagation Neural Networks (BPNN), K-Nearest Neighbor (KNN) and the Generalized Linear Mixed Model (GLMM). Models based on the RF algorithm emerged as being the best among the five algorithms irrespective of the datasets used. The Random Forest AGB model, using only LiDAR data (R2 = 0.899, RMSE = 14.0 t/ha) as the input data, was more effective than the one using optical data (R2 = 0.835, RMSE = 22.724 t/ha). Compared to LiDAR or optical data alone, the AGB model (R2 = 0.913, RMSE = 13.352 t/ha) that used the RF algorithm and integrated LiDAR and optical data was found to be optimal. Incorporation of terrain variables with optical data resulted in only slight improvements in accuracy. The models developed in this study could be useful for using integrated airborne LiDAR and passive optical data to accurately estimate forest biomass.
Highlights
Forests are the dominant carbon stock in terrestrial ecosystems and play a vital role in reducing concentrations of greenhouse gases in the atmosphere and slowing down global warming [1,2]
Comparing the accuracy of the model using a single data source for estimating forest Aboveground Biomass (AGB), Light Detection And Ranging (LiDAR) data as input variables were more effective than optical data
The biggest variation of estimation accuracies between LiDAR and optical data was in models using the Support Vector Machines (SVM) method, and the values reached 0.21 for R2 and 7.06 t/ha for Root Mean Square Error (RMSE)
Summary
Forests are the dominant carbon stock in terrestrial ecosystems and play a vital role in reducing concentrations of greenhouse gases in the atmosphere and slowing down global warming [1,2]. Forest Aboveground Biomass (AGB) is a key biophysical parameter for measuring carbon and is generally used to quantify the contribution of forests to the global carbon cycle [3]. Rapid and accurate estimation of forest aboveground biomass can greatly reduce the uncertainty in carbon stock assessments [4]. Various types of remote-sensing data are used for forest biomass estimation: optical sensor data, radio detection and ranging (radar) data, Light Detection And Ranging (LiDAR) data [10], etc. Each of these data sources has its own advantages and disadvantages for estimating forest biomass
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