A comparison of machine learning surrogate models of street-scale flooding in Norfolk, Virginia

Machine learning with applications Pub Date : 2023-11-29 DOI:10.1016/j.mlwa.2023.100518

Diana McSpadden , Steven Goldenberg , Binata Roy , Malachi Schram , Jonathan L. Goodall , Heather Richter

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Abstract

Low-lying coastal cities, exemplified by Norfolk, Virginia, face the challenge of street flooding caused by rainfall and tides, which strain transportation and sewer systems and can lead to personal and property damage. While high-fidelity, physics-based simulations provide accurate predictions of urban pluvial flooding, their computational complexity renders them unsuitable for real-time applications. Using data from Norfolk rainfall events between 2016 and 2018, this study compares the performance of a previous surrogate model based on a random forest algorithm with two deep learning models: Long Short-Term Memory (LSTM) and Gated Recurrent Unit (GRU). The comparison of deep learning to the random forest algorithm is motivated by the desire to utilize a machine learning architecture that allows for the future inclusion of common uncertainty quantification techniques and the effective integration of relevant, multi-modal features.

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弗吉尼亚州诺福克市街头洪水的机器学习替代模型的比较

以弗吉尼亚州诺福克为例的低洼沿海城市面临着由降雨和潮汐引起的街道洪水的挑战，这给交通和下水道系统带来了压力，并可能导致人身和财产损失。虽然高保真度、基于物理的模拟提供了城市洪水的准确预测，但其计算复杂性使其不适合实时应用。本研究利用2016年至2018年诺福克降雨事件的数据，将之前基于随机森林算法的替代模型与两种深度学习模型(长短期记忆(LSTM)和门控循环单元(GRU))的性能进行了比较。将深度学习与随机森林算法进行比较的动机是希望利用一种机器学习架构，该架构允许未来包含常见的不确定性量化技术，并有效整合相关的多模态特征。

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Machine learning with applications Management Science and Operations Research, Artificial Intelligence, Computer Science Applications

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98 days