Abstract
Documenting the impacts of climate change and human activities on tropical rainforests is imperative for protecting tropical biodiversity and for better implementation of REDD+ and UN Sustainable Development Goals. Recent advances in very high-resolution satellite sensor systems (i.e., WorldView-3), computing power, and machine learning (ML) have provided improved mapping of fine-scale changes in the tropics. However, approaches so far focused on feature extraction or the extensive tuning of ML parameters, hindering the potential of ML in forest conservation mapping by not using textural information, which is found to be powerful for many applications. Additionally, the contribution of shortwave infrared (SWIR) bands in forest cover mapping is unknown. The objectives were to develop end-to-end mapping of the tropical forest using fully convolution neural networks (FCNNs) with WorldView-3 (WV-3) imagery and to evaluate human impact on the environment using the Betampona Nature Reserve (BNR) in Madagascar as the test site. FCNN (U-Net) using spatial/textural information was implemented and compared with feature-fed pixel-based methods including Support Vector Machine (SVM), Random Forest (RF), and Deep Neural Network (DNN). Results show that the FCNN model outperformed other models with an accuracy of 90.9%, while SVM, RF, and DNN provided accuracies of 88.6%, 84.8%, and 86.6%, respectively. When SWIR bands were excluded from the input data, FCNN provided superior performance over other methods with a 1.87% decrease in accuracy, while the accuracies of other models—SVM, RF, and DNN—decreased by 5.42%, 3.18%, and 8.55%, respectively. Spatial–temporal analysis showed a 0.7% increase in Evergreen Forest within the BNR and a 32% increase in tree cover within residential areas likely due to forest regeneration and conservation efforts. Other effects of conservation efforts are also discussed.
Highlights
The REDD+ (Reducing Emissions from Deforestation and Forest Degradation) program identifies halting and reversing forest loss and degradation, which is essential for mitigating climate change effects [1,2]
The Support Vector Machine (SVM), Random Forest (RF), and Deep Neural Network (DNN) models produced an overall accuracy of 88.6%, 84.8%, and 86.6% respectively
The decrease in accuracy without shortwave infrared (SWIR) bands was much greater for DNN (8.55%), SVM (5.42%) and RF
Summary
The REDD+ (Reducing Emissions from Deforestation and Forest Degradation) program identifies halting and reversing forest loss and degradation, which is essential for mitigating climate change effects [1,2]. To implement REDD+ objectives at the national level, it is imperative to develop methodologies to accurately estimate forest types, forest cover area, forest degradation, and change as well as all forest restoration due to conservation efforts supported by the REDD+ program using satellite remote sensing. The study area provides a living laboratory for the studies of human–forest interactions, which has significant impact on our understanding of tropical forests and biodiversity at the global scale for better implementation of REDD+
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