Abstract
The synthetic aperture radar (SAR) imagery has been widely applied for flooding mapping based on change detection approaches. However, errors in the mapping result are expected since not all land-cover changes are flood-induced, and those changes are sensitive to SAR data, such as crop growth or harvest over agricultural lands, clearance of forested areas, and/or modifications on the urban landscape. This study, therefore, incorporated historical SAR images to boost the detection of flood-induced changes during extreme weather events, using the Long Short-Term Memory (LSTM) method. Additionally, to incorporate the spatial signatures for the change detection, we applied a deep learning-based spatiotemporal simulation framework, Convolutional Long Short-Term Memory (ConvLSTM), for simulating a synthetic image using Sentinel One intensity time series. This synthetic image will be prepared in advance of flood events, and then it can be used to detect flood areas using change detection when the post-image is available. Practically, significant divergence between the synthetic image and post-image is expected over inundated zones, which can be mapped by applying thresholds to the Delta image (synthetic image minus post-image). We trained and tested our model on three events from Australia, Brazil, and Mozambique. The generated Flood Proxy Maps were compared against reference data derived from Sentinel Two and Planet Labs optical data. To corroborate the effectiveness of the proposed methods, we also generated Delta products for two baseline models (closest post-image minus pre-image and historical mean minus post-image) and two LSTM architectures: normal LSTM and ConvLSTM. Results show that thresholding of ConvLSTM Delta yielded the highest Cohen’s Kappa coefficients in all study cases: 0.92 for Australia, 0.78 for Mozambique, and 0.68 for Brazil. Lower Kappa values obtained in the Mozambique case can be subject to the topographic effect on SAR imagery. These results still confirm the benefits in terms of classification accuracy that convolutional operations provide in time series analysis of satellite data employing spatially correlated information in a deep learning framework.
Highlights
Of all weather-related natural disasters, floods are thought to be the most widespread, recurring, and disastrous [1]
In our previous study [40], we focused on this case to develop a texture-based Bayesian probability approach for flood mapping employing the Normalized Difference SigmaNaught Index (NDSI) and Shannon’s Entropy of NDSI (SNDSI)
In terms of the number of deaths and volume of waste material released, this incident is considered to be the fifth-largest dam failure in history [45]. This event was selected to explore the applicability of the proposed method on natural disasters other than flooding and its effectiveness over mountainous terrains that pose a challenge to synthetic aperture radar (SAR)-based change detection methods
Summary
Of all weather-related natural disasters, floods are thought to be the most widespread, recurring, and disastrous [1]. It is possible to analyze the temporal signature of the pixel value If this process is repeated for every pixel that makes up the 2-D image, we can generate a synthetic image, representing expected values for the time step. For this purpose, the Long Short-Term Memory (LSTM), which is an artificial Recurrent Neural. To incorporate the spatial signatures for the change detection, a modified deep learning architecture, Convolutional Long Short-Term Memory (ConvLSTM) was applied for simulating the synthetic image using Sentinel One intensity time series. Big Data Cloud infrastructures such as Google Earth Engine (GEE) [19], allowing for on-demand analysis scalability in temporal and spatial domains
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