通过耦合基于过程的模型和深度学习模型,改进流域水质建模的混合方法。

IF 2.5 4区 环境科学与生态学 Q3 ENGINEERING, ENVIRONMENTAL
Dae Seong Jeong, Heewon Jeong, Jin Hwi Kim, Joon Ha Kim, Yongeun Park
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引用次数: 0

摘要

预测水质变化的流域水质模型是在流域内制定有效管理策略的重要工具。基于过程的模型(PBM)通常用于模拟水质模型。在利用 PBM 进行流域建模时,通过适当设置模型参数来有效反映实际流域条件至关重要。然而,参数校准和验证过程耗时且存在固有的不确定性。为应对这些挑战,本研究旨在解决 PBM 校准和验证过程中遇到的各种难题。为此,我们提出开发一种混合模型,将未经校准的 PBM 与数据驱动模型(DDM)(如深度学习算法)相结合。该混合模型旨在通过整合 PBM 和 DDM 的优势来加强流域建模。该混合模型是通过将未经校准的水土评估工具(SWAT)与长短期记忆(LSTM)相结合而构建的。SWAT 是一种具有代表性的 PBM,它是利用地理信息和灵山江流域的 5 年观测数据构建的。未经校准的 SWAT 输出变量,如河水流量、悬浮固体(SS)、总氮(TN)和总磷(TP),以及当天和前一天的观测降水量,被用作深度学习模型预测 TP 负荷的训练数据。为了进行比较,对传统的 SWAT 模型进行了校准和验证,以预测 TP 负荷。结果显示,混合模型模拟的 TP 负荷比校准过的 SWAT 模型预测的观测 TP 更准确。此外,混合模型还反映了 TP 负荷的季节性变化,包括峰值事件。值得注意的是,在没有经过特定训练的情况下,将混合模型应用于其他子流域时,混合模型的表现始终优于经过校准的 SWAT 模型。总之,SWAT-LSTM 混合模型的应用可以作为一种有用的工具,减少模型校准中的不确定性,提高流域模型的整体预测性能。实践要点:我们的目标是为流域水质建模增强基于过程的模型。水土评估工具-长短期记忆混合模型的预测结果和总磷(TP)与观测到的总磷(TP)相吻合。在应用于其他子流域时,该模型表现出更优越的预测性能。混合模型将克服传统建模的限制。它还将使建模更加有效和高效。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A hybrid approach to improvement of watershed water quality modeling by coupling process-based and deep learning models.

Watershed water quality modeling to predict changing water quality is an essential tool for devising effective management strategies within watersheds. Process-based models (PBMs) are typically used to simulate water quality modeling. In watershed modeling utilizing PBMs, it is crucial to effectively reflect the actual watershed conditions by appropriately setting the model parameters. However, parameter calibration and validation are time-consuming processes with inherent uncertainties. Addressing these challenges, this research aims to address various challenges encountered in the calibration and validation processes of PBMs. To achieve this, the development of a hybrid model, combining uncalibrated PBMs with data-driven models (DDMs) such as deep learning algorithms is proposed. This hybrid model is intended to enhance watershed modeling by integrating the strengths of both PBMs and DDMs. The hybrid model is constructed by coupling an uncalibrated Soil and Water Assessment Tool (SWAT) with a Long Short-Term Memory (LSTM). SWAT, a representative PBM, is constructed using geographical information and 5-year observed data from the Yeongsan River Watershed. The output variables of the uncalibrated SWAT, such as streamflow, suspended solids (SS), total nitrogen (TN), and total phosphorus (TP), as well as observed precipitation for the day and previous day, are used as training data for the deep learning model to predict the TP load. For the comparison, the conventional SWAT model is calibrated and validated to predict the TP load. The results revealed that TP load simulated by the hybrid model predicted the observed TP better than that predicted by the calibrated SWAT model. Also, the hybrid model reflects seasonal variations in the TP load, including peak events. Remarkably, when applied to other sub-basins without specific training, the hybrid model consistently outperformed the calibrated SWAT model. In conclusion, application of the SWAT-LSTM hybrid model could be a useful tool for decreasing uncertainties in model calibration and improving the overall predictive performance in watershed modeling. PRACTITIONER POINTS: We aimed to enhance process-based models for watershed water-quality modeling. The Soil and Water Assessment Tool-Long Short-Term Memory hybrid model's predicted and total phosphorus (TP) matched the observed TP. It exhibited superior predictive performance when applied to other sub-basins. The hybrid model will overcome the constraints of conventional modeling. It will also enable more effective and efficient modeling.

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来源期刊
Water Environment Research
Water Environment Research 环境科学-工程:环境
CiteScore
6.30
自引率
0.00%
发文量
138
审稿时长
11 months
期刊介绍: Published since 1928, Water Environment Research (WER) is an international multidisciplinary water resource management journal for the dissemination of fundamental and applied research in all scientific and technical areas related to water quality and resource recovery. WER''s goal is to foster communication and interdisciplinary research between water sciences and related fields such as environmental toxicology, agriculture, public and occupational health, microbiology, and ecology. In addition to original research articles, short communications, case studies, reviews, and perspectives are encouraged.
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