Prediction of River Stage Using Multistep-Ahead Machine Learning Techniques for a Tidal River of Taiwan

Wen-Dar Guo,Chih-Hsin Chang,Sen-Hai Yeh,Wei-Bo Chen,Hongey Chen

doi:10.3390/w13070920

Wen-Dar Guo, Chih-Hsin Chang + Show 3 more

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https://doi.org/10.3390/w13070920

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Abstract

Time-series prediction of a river stage during typhoons or storms is essential for flood control or flood disaster prevention. Data-driven models using machine learning (ML) techniques have become an attractive and effective approach to modeling and analyzing river stage dynamics. However, relatively new ML techniques, such as the light gradient boosting machine regression (LGBMR), have rarely been applied to predict the river stage in a tidal river. In this study, data-driven ML models were developed under a multistep-ahead prediction framework and evaluated for river stage modeling. Four ML techniques, namely support vector regression (SVR), random forest regression (RFR), multilayer perceptron regression (MLPR), and LGBMR, were employed to establish data-driven ML models with Bayesian optimization. The models were applied to simulate river stage hydrographs of the tidal reach of the Lan-Yang River Basin in Northeastern Taiwan. Historical measurements of rainfall, river stages, and tidal levels were collected from 2004 to 2017 and used for training and validation of the four models. Four scenarios were used to investigate the effect of the combinations of input variables on river stage predictions. The results indicated that (1) the tidal level at a previous stage significantly affected the prediction results; (2) the LGBMR model achieves more favorable prediction performance than the SVR, RFR, and MLPR models; and (3) the LGBMR model could efficiently and accurately predict the 1–6-h river stage in the tidal river. This study provides an extensive and insightful comparison of four data-driven ML models for river stage forecasting that can be helpful for model selection and flood mitigation.

Highlights

Accurate river stage forecasting is a crucial component in the flood early warning system and plays a key role in flood disaster mitigation
The present study developed four data-driven machine learning (ML) models (SVR, random forest regression (RFR), multilayer perceptron regression (MLPR), and light gradient boosting machine regression (LGBMR) models) for direct multistep forecasting; among these models, the LGBMR model is relatively new and has rarely been applied for the prediction of river floods
This study presents a multistep-ahead framework involving Bayesian optimization to construct data-driven prediction models based on four ML techniques, namely support vector regression (SVR), RFR, MLPR, and LGBMR, for river stage forecasting

Summary

Introduction

Accurate river stage forecasting is a crucial component in the flood early warning system and plays a key role in flood disaster mitigation. Typhoon Morakot hit Taiwan in 2009, resulting in a torrential rainfall of 2748 mm in only 72 h [2]. Such an extreme rainfall caused compound hazards, such as floods, river overflows, landslides, river embankment failures, and driftwood accumulation. The flood warning system is a vital mitigation technique during natural disasters that can be used by river managers to make decisions before the arrival of a typhoon. Studies on accurate and reliable river stage forecasting are required to reduce the impact of flood disasters

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