Abstract
Wildfires are one of the most destructive natural disasters that can affect our environment, with significant effects also on wildlife. Recently, climate change and human activities have resulted in higher frequencies of wildfires throughout the world. Timely and accurate detection of the burned areas can help to make decisions for their management. Remote sensing satellite imagery can have a key role in mapping burned areas due to its wide coverage, high-resolution data collection, and low capture times. However, although many studies have reported on burned area mapping based on remote sensing imagery in recent decades, accurate burned area mapping remains a major challenge due to the complexity of the background and the diversity of the burned areas. This paper presents a novel framework for burned area mapping based on Deep Siamese Morphological Neural Network (DSMNN-Net) and heterogeneous datasets. The DSMNN-Net framework is based on change detection through proposing a pre/post-fire method that is compatible with heterogeneous remote sensing datasets. The proposed network combines multiscale convolution layers and morphological layers (erosion and dilation) to generate deep features. To evaluate the performance of the method proposed here, two case study areas in Australian forests were selected. The framework used can better detect burned areas compared to other state-of-the-art burned area mapping procedures, with a performance of >98% for overall accuracy index, and a kappa coefficient of >0.9, using multispectral Sentinel-2 and hyperspectral PRISMA image datasets. The analyses of the two datasets illustrate that the DSMNN-Net is sufficiently valid and robust for burned area mapping, and especially for complex areas.
Highlights
Introduction iationsAs a natural hazard, wildfires represent one of the most important reasons for the evolution of ecosystems in the Earth’s system on a global scale [1,2,3]
The results for the Burned area mapping (BAM) for the two study areas are considered
A novel framework based on a deep-learning method (DSMNN-Net) and the use of bi-temporal multispectral and hyperspectral datasets was proposed
Summary
Introduction iationsAs a natural hazard, wildfires represent one of the most important reasons for the evolution of ecosystems in the Earth’s system on a global scale [1,2,3]. The frequency of occurrence of wildfires has increased significantly due to climate change and human activities around the world [4,5]. Wildfires can be influenced by the environment from different aspects, such as soil erosion, increasing flood risk, and habitat degradation for wildlife [6,7]. Wildfires generate a wide range of pollutants, including greenhouse gases (i.e., methane and carbon dioxide) [8]. Burned area mapping (BAM) can be useful to predict the behavior of a fire, to define the burning biomass, for compensation from insurance companies, and for estimation of greenhouse gases emitted [9,10]. The generation of reliable and accurate burned area maps is necessary for their management and planning in the support of decision
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