Conditional seasonal markov-switching autoregressive model to simulate extreme events: Application to river flow

IF 4.8 2区 环境科学与生态学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS Environmental Modelling & Software Pub Date : 2024-05-13 DOI:10.1016/j.envsoft.2024.106066
Bassel Habeeb , Emilio Bastidas-Arteaga , Mauricio Sánchez-Silva , You Dong
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Abstract

Extreme events have the potential to significantly impact transportation infrastructure performance. For example, in the case of bridges, climate change impacts the river discharge, hence scouring patterns, which in turn, affects the bridge foundation stability. Therefore, extreme events (river flow) forecasting is mandatory in bridge reliability analysis. This paper approaches this river flow forecasting problem by developing a Markov-Switching Autoregressive model coupled with a conditional hidden seasonal Markov component. In addition, the proposed model is also combined with the deep machine learning neural networks method to forecast river flow from a dataset or from simulations. The proposed method is illustrated by using realistic data: historic river flow values of the Thames River. The results indicate that the proposed model well represented the extreme events within the dataset. In terms of river flow forecasting, the results indicate that the forecasts improve when the training period changes from 20 years to 40 years.

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模拟极端事件的条件季节性马尔可夫开关自回归模型:河流流量应用
极端事件有可能严重影响交通基础设施的性能。例如,就桥梁而言,气候变化会影响河流流量,进而影响冲刷模式,反过来又会影响桥梁地基的稳定性。因此,在桥梁可靠性分析中,极端事件(河流流量)预测是必不可少的。本文通过建立一个马尔可夫切换自回归模型,并结合条件隐藏季节马尔可夫成分,来解决河水流量预报问题。此外,所提出的模型还与深度机器学习神经网络方法相结合,从数据集或模拟中预测河流流量。通过使用现实数据:泰晤士河的历史河流流量值,对所提出的方法进行了说明。结果表明,所提出的模型很好地代表了数据集中的极端事件。在河流流量预测方面,结果表明,当训练期从 20 年变为 40 年时,预测结果有所改善。
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来源期刊
Environmental Modelling & Software
Environmental Modelling & Software 工程技术-工程:环境
CiteScore
9.30
自引率
8.20%
发文量
241
审稿时长
60 days
期刊介绍: Environmental Modelling & Software publishes contributions, in the form of research articles, reviews and short communications, on recent advances in environmental modelling and/or software. The aim is to improve our capacity to represent, understand, predict or manage the behaviour of environmental systems at all practical scales, and to communicate those improvements to a wide scientific and professional audience.
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