Abstract
This paper presents an application of a novel machine-learning framework on MODIS (moderate-resolution imaging spectroradiometer) data to map burned areas over tropical forests of South America and South-east Asia. The RAPT (RAre Class Prediction in the absence of True labels) framework is able to build data adaptive classification models using noisy training labels. It is particularly suitable when expert annotated training samples are difficult to obtain as in the case of wild fires in the tropics. This framework has been used to build burned area maps from MODIS surface reflectance data as features and Active Fire hotspots as training labels that are known to have high commission and omission errors due to the prevalence of cloud cover and smoke, especially in the tropics. Using the RAPT framework we report burned areas for 16 MODIS tiles from 2001 to 2014. The total burned area detected in the tropical forests of South America and South-east Asia during these years is 2,071,378 MODIS (500 m) pixels (approximately 520 K sq. km.), which is almost three times compared to the estimates from collection 5 MODIS MCD64A1 (783,468 MODIS pixels). An evaluation using Landsat-based reference burned area maps indicates that our product has an average user’s accuracy of 53% and producer’s accuracy of 55% while collection 5 MCD64A1 burned area product has an average user’s accuracy of 61% and producer’s accuracy of 27%. Our analysis also indicates that the two products can be complimentary and a combination of the two approaches is likely to provide a more comprehensive assessment of tropical fires. Finally, we have created a publicly accessible web-based viewer that helps the community to visualize the burned area maps produced using RAPT and examine various validation sources corresponding to every detected MODIS pixel.
Highlights
Forest fires are known to generate a significant flux of greenhouse gases and particulate matter into the atmosphere and contribute to several ecological effects such as the loss of animal habitat and biodiversity [1]
This paper presents a new post-fire burned area product that is relevant for tropical forests where both of these issues are very common
The MCD64 product is the primary source of the Global Fire Emissions Database (GFED) Version 4 [24]
Summary
Forest fires are known to generate a significant flux of greenhouse gases and particulate matter into the atmosphere and contribute to several ecological effects such as the loss of animal habitat and biodiversity [1]. Existing satellite-based techniques for burn area assessment can be grouped into two broad categories-active fire (hotspot) detection and post-fire burned area mapping. Hotspot detection approaches use thermal energy associated with burning of biomass to map active (ongoing) fires with the purpose of real-time fire management. Post-fire burned area mapping techniques consider satellite observations of the land surface over a longer temporal interval around the burn date to create more reliable historical maps of burned areas [8,10,11,12,13,14]. Note that post-fire mapping techniques are relatively more robust to issues due to cloud cover or smoke from fires because often burn scars remain detectable in the spectral observations for several months after the burn date. This paper presents a new post-fire burned area product that is relevant for tropical forests where both of these issues are very common
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