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Original Research | Open Access

Physics-guided networks for probabilistic hydrodynamic forecasting in canal systems

Wangjiayi LiuaGuanghua Guana( )Xiaonan ChenbLiangsheng ShiaGuangtao FucDragan Savicc,d
State Key Laboratory of Water Resources Engineering and Management, Wuhan University, Wuhan, 430072, China
Construction and Administration Bureau of the Middle-Route of the South-to-North Water Division Project of China, Beijing, 100038, China
Centre for Water Systems, University of Exeter, Exeter, EX4 4QF, United Kingdom
KWR Water Research Institute, Groningenhaven 7, Nieuwegein, 3430 BB, Netherlands
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Abstract

Reliable prediction of water supply dynamics in large-scale canal systems is critical for water allocation and operational decision-making in inter-basin water transfer projects. Uncertainty in lateral offtake discharges evolves over time and often exhibits multi-peaked distributions due to real-time hydraulic states and unplanned gate operations. However, reliably quantifying and interpreting the evolving uncertainty remains difficult under such dynamically changing and small-sample conditions. Here we show that a physics-guided mixture density network (PgMDN) can effectively characterize this uncertainty while remaining physically consistent. In the proposed PgMDN, physical knowledge is incorporated into the loss function through local mass balance and a consistency constraint between predictions and their associated uncertainty, while long short-term memory layers are employed to model temporal dependencies and multi-factor influences. In addition, Shapley additive explanation analysis is used to identify the dominant hydraulic inputs contributing to predictive uncertainty. Tested on real-world canal datasets, the proposed PgMDN outperforms the standard mixture density network, achieving over a 25% reduction in both mean absolute error and root mean square error, together with improved reliability, as measured by the R-index (increasing from 0.45 to 0.82), and stronger generalization. The results further reveal that water level fluctuations and boundary inflow are key drivers of predictive uncertainty, supporting the physical interpretability of the proposed model. Overall, this study provides a scalable and interpretable tool for real-time modeling of environmental infrastructure and the operational management of large-scale water diversion systems.

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Environmental Science and Ecotechnology

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Cite this article:
Liu W, Guan G, Chen X, et al. Physics-guided networks for probabilistic hydrodynamic forecasting in canal systems. Environmental Science and Ecotechnology, 2026, 31. https://doi.org/10.1016/j.ese.2026.100703

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Received: 01 July 2025
Revised: 29 April 2026
Accepted: 02 May 2026
Published: 01 May 2026
© 2026 The Authors. Chinese Society for Environmental Sciences, Harbin Institute of Technology, Chinese Research Academy of Environmental Sciences.

This is an open access article under the CC BY license (http://creativecommons.org/licenses/by/4.0/).