Abstract
The REDD+ framework requires accurate estimates of deforestation. These are derived by ground measurements supported by methods based on remote sensing data to automatically detect and delineate deforestations over large areas. In particular, in the tropics, optical data is seldom available due to cloud cover. As synthetic aperture radar (SAR) data overcomes this limitation, we performed a separability analysis of two statistical metrics based on the Sentinel-1 SAR backscatter over forested and deforested areas. We compared the range between the 5th and 95th temporal percentiles (PRange) and the recurrence quantification analysis (RQA) Trend metric. Unlike the PRange, the RQA Trend considers the temporal order of the SAR data acquisitions, thus contrasting between dropping backscatter signals and yearly seasonalities. This enables the estimation of the timing of deforestation events. We assessed the impact of polarization, acquisition orbit, and despeckling on the separability between forested and deforested areas and between different deforestation timings for two test sites in Mexico. We found that the choice of the orbit impacts the detectability of deforestation. In all cases, VH data showed a higher separability between forest and deforestations than VV data. The PRange slightly outperformed RQA Trend in the separation between forest and deforestation. However, the RQA Trend exceeded the PRange in the separation between different deforestation timings. In this study, C-Band backscatter data was used, although it is commonly not considered as the most suitable SAR dataset for forestry applications. Nevertheless, our approach shows the potential of dense C-Band backscatter time series to support the REDD+ framework.
Highlights
T HE tropical forest ecosystems stabilize the world climate [1] and protect global biodiversity [2]
Since deforestation leads to a drop in backscatter, the PRange and the recurrence quantification analysis (RQA) Trend both succeed in separating deforestation from stable forest areas in Sentinel-1 C-Band synthetic aperture radar (SAR) data
We investigated the use of multitemporal metrics of hypertemporal Sentinel-1 backscatter time series to separate stable forest from deforestation
Summary
T HE tropical forest ecosystems stabilize the world climate [1] and protect global biodiversity [2]. Forest cover and forest cover change can be mapped using cloud penetrating synthetic aperture radar (SAR) data. These maps are mostly based on L-Band SAR data because the longer wavelength penetrates deeper into the forest structure [4] or on X-Band SAR interferometry data [5]. There exists no freely available global SAR L-Band time series dataset. This will change in the near future once the NASA-ISRO L-Band sensor NISAR is launched. The European Copernicus Programme provides a global SAR C-Band dataset with a high spatial The European Copernicus Programme provides a global SAR C-Band dataset with a high spatial (ca. 10 m) and temporal resolution (six days)
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
