Machine Learning Methods Based on Storm Surge Disaster Loss in Computing Applications
Keywords:
Storm surge, ConvLSTM, natural disasters, efficient, machine learning, water levelAbstract
Storm surge, which impacts the entire coastline region, is China's most serious marine calamity. Storm surge disaster loss (SSDL) estimation is important for decision-making, sustainability, and disaster prevention. For early warning systems, disaster management, and disaster evaluation, an accurate storm surge water level forecast is essential. Comparing machine learning techniques to numerical simulation techniques, the former is more straightforward and efficient. Still, point predictions are the main focus of the majority of current machine learning-based research on storm surge prediction. In this paper, we explore the feasibility of employing the ConvLSTM model for spatial water level prediction. The ConvLSTM-based methodology is simpler, faster, and more accurate in predicting water levels without the need for boundary conditions or topography than standard numerical simulation methods. In addition, we take worst-case situations into account by employing the random forest model to anticipate the highest possible water increase. Based on our findings, the random forest model may prove to be a useful instrument in determining the highest water increase value linked to typhoon storm surges, which can help with efficient emergency reactions during natural disasters.
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Copyright (c) 2023 M. Mohammed Thaha, Izwan Nizal Mohd Shaharanee, V. P. Murugan, T. P. S. Kumar Kusumanchi, D. V. Lokeswar Reddy
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