A Rapid Prediction Model of Urban Flood Inundation in a High-Risk Area Coupling Machine Learning and Numerical Simulation Approaches

Xingyu Yan,Wenqiang Feng,Kui Xu,Jing Chen

doi:10.1007/s13753-021-00384-0

Xingyu Yan, Wenqiang Feng + Show 2 more

Open Access

https://doi.org/10.1007/s13753-021-00384-0

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Abstract

Climate change has led to increasing frequency of sudden extreme heavy rainfall events in cities, resulting in great disaster losses. Therefore, in emergency management, we need to be timely in predicting urban floods. Although the existing machine learning models can quickly predict the depth of stagnant water, these models only target single points and require large amounts of measured data, which are currently lacking. Although numerical models can accurately simulate and predict such events, it takes a long time to perform the associated calculations, especially two-dimensional large-scale calculations, which cannot meet the needs of emergency management. Therefore, this article proposes a method of coupling neural networks and numerical models that can simulate and identify areas at high risk from urban floods and quickly predict the depth of water accumulation in these areas. Taking a drainage area in Tianjin Municipality, China, as an example, the results show that the simulation accuracy of this method is high, the Nash coefficient is 0.876, and the calculation time is 20 seconds. This method can quickly and accurately simulate the depth of water accumulation in high-risk areas in cities and provide technical support for urban flood emergency management.

Highlights

Global climate change has affected the intensity and patterns of rainfall, which in turn has affected runoff (May 2008; Hammond et al 2015)
Taking a drainage area in Tianjin Municipality, China, as an example, the results show that the simulation accuracy of this method is high, the Nash coefficient is 0.876, and the calculation time is 20 seconds
Aiming at the prediction of accumulated water in flood emergencies in an urban area, this study proposed a prediction model of the maximum water depth in time and space employing a neural network-numerical simulation model on the basis of coupling a two-dimensional hydrological and hydrodynamic model and a statistical analysis model

Summary

Introduction

Global climate change has affected the intensity and patterns of rainfall, which in turn has affected runoff (May 2008; Hammond et al 2015). This has led to frequent flooding, causing heavy economic losses and casualties (Banik et al 2015). Failure to respond quickly to floods causes great losses, and rapid response is based on rapid and accurate forecasting. Predicting flood disasters is a key component to providing decision makers with sufficient time to act and minimize disaster losses (Marıa et al 2020)

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Conclusion