Physics-informed neural networks in water and wastewater systems: a critical review

人工神经网络 外推法 鉴定(生物学) 计算机科学 一致性(知识库) 趋同(经济学) 系统标识 偏微分方程 一般化 反问题 废水 数学优化 人工智能 桥(图论) 边界(拓扑) 估计理论 工作(物理) 边值问题 机器学习 参数辨识问题 稳健性(进化) 控制工程 工程类 合流下水道
作者
Antonino Di Bella,Maziar Raissi,Domenico Santoro,Paolo Roccaro
出处
期刊:Water Research [Elsevier BV]
卷期号:293: 125449-125449 被引量:5
标识
DOI:10.1016/j.watres.2026.125449
摘要

Physics-Informed Neural Networks (PINNs) represent a hybrid modeling paradigm that embeds governing physical laws, expressed as partial differential equations (PDEs), directly into neural network training. This integration enables models to respect fundamental conservation principles while learning from sparse or incomplete data. This review critically examines PINN applications in water and wastewater systems over the period 2014-2024, focusing on drinking water distribution networks, wastewater treatment plants, urban drainage systems, and water treatment processes. The review shows that PINNs excel in inverse problem solving by enabling parameter estimation and system identification from indirect observations, while maintaining physical consistency in extrapolation regimes where purely data-driven models fail. Documented applications report performance advantages, including 3-30 × reductions in required training data compared to standard neural networks, improved generalization under distribution shift, and successful use in scenarios involving partial observations and uncertain boundary conditions. However, critical limitations emerge: PINNs require well-posed problems with reliable governing equations, struggle with complex networked systems involving discrete components, face major convergence challenges for stiff or multi-scale PDEs, and still lack mature uncertainty quantification frameworks. Rather than positioning PINNs as replacements for established numerical methods, this work frames them as complementary tools that bridge mechanistic modeling and data-driven learning, offering particular value in parameter calibration, sensor placement optimization, and real-time state estimation for water infrastructure systems.

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