Abstract
Fanjinshan National Nature Reserve (FNNR) is a biodiversity hotspot in China that is part of a larger, multi-use landscape where farming, grazing, tourism, and other human activities occur. The steep terrain and persistent cloud cover pose challenges to robust vegetation and land use mapping. Our objective is to develop satellite image classification techniques that can reliably map forest cover and land use while minimizing the cloud and terrain issues, and provide the basis for long-term monitoring. Multi-seasonal Landsat image composites and elevation ancillary layers effectively minimize the persistent cloud cover and terrain issues. Spectral vegetation index (SVI) products and shade/illumination normalization approaches yield significantly higher mapping accuracies, compared to non-normalized spectral bands. Advanced machine learning image classification routines are implemented through the cloud-based Google Earth Engine platform. Optimal classifier parameters (e.g., number of trees and number of features for random forest classifiers) were achieved by using tuning techniques. Accuracy assessment results indicate consistent and effective overall classification (i.e., above 70% mapping accuracies) can be achieved using multi-temporal SVI composites with simple illumination normalization and elevation ancillary data, despite the fact limited training and reference data are available. This efficient and open-access image analysis workflow provides a reliable methodology to remotely monitor forest cover and land use in FNNR and other mountainous forested, cloud prevalent areas.
Highlights
Despite their protected status, nature reserves can be strongly influenced by adjacent or overlapping anthropogenic activities [1]
While the most feasible and efficient means for such mapping and monitoring is through satellite remote sensing, the persistent cloud cover and steep terrain associated with the Fanjingshan National Nature Reserve (FNNR) region pose a great challenge to forest mapping with optical or microwave remote sensing approaches
This study demonstrated an effective approach to mapping vegetation cover and land use utilizing cloud-based image processing tools, even with persistent cloud cover and extreme terrain and illumination effects
Summary
Nature reserves can be strongly influenced by adjacent or overlapping anthropogenic activities [1]. To protect ecosystem services (limiting soil erosion and runoff) and FNNR biodiversity, Chinese government agencies have implemented payment for ecosystem services (PES) policies to promote afforestation, reduce logging, and limit farming on high sloping lands surrounding the Reserves [4,5,6]. China started another large PES program, the Grain-To-Green Program (GTGP) This program aims to reduce soil erosion and increase vegetation cover through tree planting in steep farmland areas (>15◦ slope in northwestern China, and 25◦ in southwestern China; [7,8]). This context makes monitoring and mapping forest vegetation and land use types an essential element of such programs. While the most feasible and efficient means for such mapping and monitoring is through satellite remote sensing, the persistent cloud cover and steep terrain associated with the FNNR region pose a great challenge to forest mapping with optical or microwave remote sensing approaches
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