Probabilistic Physics-Guided Deep Neural Networks With Recurrence and Attention Mechanisms for Interpretable Daily Streamflow Simulation

IF 5 1区地球科学 Q2 ENVIRONMENTAL SCIENCES

Water Resources Research Pub Date : 2025-09-22 DOI:10.1029/2025wr040173

Sadegh Sadeghi Tabas, Vidya Samadi, Catherine Wilson, Biswa Bhattacharya

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引用次数: 0

Abstract

As Deep Neural Networks (DNNs) are being increasingly employed to make important simulations in rainfall-runoff contexts, the demand for interpretability is increasing in the hydrology community. Interpretability is not just a scientific question, but rather knowing where the models fall flat, how to fix them, and how to explain their outcomes to scientific communities so that everyone understands how the model arrives at specific simulations This paper addresses these challenges by deciphering interpretable probabilistic DNNs utilizing the Deep Autoregressive Recurrent (DeepAR) and Temporal Fusion Transformer (TFT) for daily streamflow simulation across the continental United States (CONUS). We benchmarked TFT and DeepAR against conceptual to physics-based hydrologic models. In this setting, catchment physical attributes were incorporated into the training process to create physics-guided TFT and DeepAR configurations. Our proposed physics-guided configurations are also designed to aggregate the patterns across the entire data set, analyze the sensitivity of key catchment physical attributes and facilitate the interpretability of temporal dynamics in rainfall-runoff generation mechanisms. To assess the uncertainty, the modeling configurations were coupled with a quantile regression by adding Gaussian noise

N (0, σ) $N\,(0,\sigma )$

with increasing standard deviation to the individual catchment attributes. Analysis suggested that the physics-guided TFT was superior in predicting daily streamflow compared to the original TFT and DeepAR as well as benchmark hydrologic models. Predictive uncertainty intervals effectively bracketed most of the observational data by simultaneous simulation of various percentiles (e.g., 10th, 50th, and 90th). Interpretable physics-guided TFT proved to be a strong candidate for CONUS daily streamflow simulations.

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具有递归和注意机制的概率物理引导深度神经网络用于可解释的每日溪流模拟

随着深度神经网络（dnn）越来越多地应用于降雨径流环境的重要模拟，水文界对可解释性的需求也在增加。可解释性不仅仅是一个科学问题，更重要的是知道模型在哪里失败，如何修复它们，以及如何向科学界解释他们的结果，以便每个人都了解模型如何达到特定的模拟。本文通过利用深度自回归递归（DeepAR）和时间融合变压器（TFT）对美国大陆（CONUS）的日常流模拟解码可解释的概率dnn来解决这些挑战。我们对基于概念到物理的水文模型进行了TFT和DeepAR的基准测试。在这种情况下，集水区的物理属性被纳入到训练过程中，以创建物理指导的TFT和DeepAR配置。我们提出的物理导向配置还旨在汇总整个数据集的模式，分析关键流域物理属性的敏感性，并促进降雨-径流生成机制中时间动态的可解释性。为了评估不确定性，建模配置与分位数回归相结合，通过向单个流域属性添加高斯噪声N(0,σ)$N\,(0,\sigma)$，并随标准差的增加而增加。分析表明，与原始TFT和DeepAR以及基准水文模型相比，物理引导的TFT在预测日流量方面优于原始TFT和DeepAR。通过同时模拟不同百分位数（如第10、第50和第90个百分位数），预测不确定性区间有效地涵盖了大部分观测数据。可解释的物理引导TFT被证明是CONUS日常流模拟的有力候选。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Water Resources Research 环境科学-湖沼学

CiteScore

8.80

自引率

13.00%

发文量

599

审稿时长

3.5 months

期刊介绍： Water Resources Research (WRR) is an interdisciplinary journal that focuses on hydrology and water resources. It publishes original research in the natural and social sciences of water. It emphasizes the role of water in the Earth system, including physical, chemical, biological, and ecological processes in water resources research and management, including social, policy, and public health implications. It encompasses observational, experimental, theoretical, analytical, numerical, and data-driven approaches that advance the science of water and its management. Submissions are evaluated for their novelty, accuracy, significance, and broader implications of the findings.