Abstract
We propose a framework that estimates the inundation depth (maximum water level) and debris-flow-induced topographic deformation from remote sensing imagery by integrating deep learning and numerical simulation. A water and debris-flow simulator generates training data for various artificial disaster scenarios. We show that regression models based on Attention U-Net and LinkNet architectures trained on such synthetic data can predict the maximum water level and topographic deformation from a remote sensing-derived change detection map and a digital elevation model. The proposed framework has an inpainting capability, thus mitigating the false negatives that are inevitable in remote sensing image analysis. Our framework breaks limits of remote sensing and enables rapid estimation of inundation depth and topographic deformation, essential information for emergency response, including rescue and relief activities. We conduct experiments with both synthetic and real data for two disaster events that caused simultaneous flooding and debris flows and demonstrate the effectiveness of our approach quantitatively and qualitatively. Our code and data sets are available at <uri xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">https://github.com/nyokoya/dlsim</uri> .
Highlights
I NFORMATION about inundation depth and debris-flow-induced topographic deformation is essential for flood and debris-flow emergency response, Manuscript received June 4, 2020; revised September 13, 2020; accepted October 28, 2020
1) Quantitative Results: Table I shows the accuracy of the estimated maximum water level and topographic deformation calculated by the regression models based on Attention U-Net, LinkNet, and their fusion
The average simulation shows better LSHI values for Western Japan 2018. The reason for this result is that the average simulation uses the same parameters as the test case and the scale of the disaster is very similar to each test case, while the regression model uses all the training data generated with the different parameters and the scale of the disaster is not optimized
Summary
I NFORMATION about inundation depth (maximum water level) and debris-flow-induced topographic deformation is essential for flood and debris-flow emergency response, Manuscript received June 4, 2020; revised September 13, 2020; accepted October 28, 2020. Kazuki Yamanoi is with the Disaster Prevention Research Institute, Kyoto University, Kyoto 612-8235, Japan, and with the RIKEN Center for Computational Science, Kobe 650-0047, Japan (e-mail: yamanoi.kazuki.6s@ kyoto-u.ac.jp). Numerical simulation models are capable of calculating the realistic maximum water level and topographic deformation; they require accurate input data and time-consuming parameter tuning
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