Improved forecasting via physics-guided machine learning as exemplified using “21·7” extreme rainfall event in Henan

IF 6 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Qi Zhong, Zhicha Zhang, Xiuping Yao, Shaoyu Hou, Shenming Fu, Yong Cao, Linguo Jing
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引用次数: 0

Abstract

As a natural disaster, extreme precipitation is among the most destructive and influential, but predicting its occurrence and evolution accurately is very challenging because of its rarity and uniqueness. Taking the example of the “21·7” extreme precipitation event (17–21 July 2021) in Henan Province, this study explores the potential of using physics-guided machine learning to improve the accuracy of forecasting the intensity and location of extreme precipitation. Three physics-guided ways of embedding physical features, fusing physical model forecasts and revised loss function are used, i.e., (1) analyzing the anomalous circulation and thermodynamical factors, (2) analyzing the multi-model forecast bias and the associated underlying reasons for it, and (3) using professional forecasting knowledge to design the loss function, and the corresponding results are used as input for machine learning to improve the forecasting accuracy. The results indicate that by learning the relationship between anomalous physical features and heavy precipitation, the forecasting of precipitation intensity is improved significantly, but the location is rarely adjusted and more false alarms appear. Possible reasons for this are as follows. The anomalous features used here mainly contain information about large-scale systems and factors which are consistent with the model precipitation deviation; moreover, the samples of extreme precipitation are sparse and so the algorithm used here is simple. However, by combining “good and different” multi models with machine learning, the advantages of each model are extracted and then the location of the precipitation center in the forecast is improved significantly. Therefore, by combining the appropriate anomalous features with multi-model fusion, an integrated improvement of the forecast of the rainfall intensity and location is achieved. Overall, this study is a novel exploration to improve the refined forecasting of heavy precipitation with extreme intensity and high variability, and provides a reference for the deep fusion of physics and artificial intelligence methods to improve intense rain forecast.

以河南 "21-7 "极端降雨事件为例,通过物理引导的机器学习改进预报工作
作为一种自然灾害,极端降水的破坏力和影响力最大,但由于其罕见性和独特性,准确预测其发生和演变非常具有挑战性。本研究以河南省 "21-7 "极端降水事件(2021 年 7 月 17-21 日)为例,探讨了利用物理引导的机器学习提高极端降水强度和位置预报精度的潜力。研究采用了嵌入物理特征、融合物理模式预报和修正损失函数三种物理引导的方法,即:(1)分析异常环流和热力学因素;(2)分析多模式预报偏差及其相关内在原因;(3)利用专业预报知识设计损失函数,并将相应结果作为机器学习的输入,以提高预报精度。结果表明,通过学习异常物理特征与强降水之间的关系,降水强度的预报得到明显改善,但位置很少调整,出现较多误报。可能的原因如下。这里使用的异常特征主要包含与模式降水偏差一致的大尺度系统和因素信息;此外,极端降水样本稀少,因此这里使用的算法比较简单。然而,通过机器学习将 "良莠不齐 "的多模型结合起来,提取各模型的优势,预报中降水中心的位置就会得到明显改善。因此,通过将适当的异常特征与多模型融合相结合,可以实现降雨强度和位置预报的综合改进。总之,该研究是对改善极端强度和高变率强降水精细化预报的一次新探索,为物理与人工智能方法深度融合改善强降雨预报提供了参考。
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
Science China Earth Sciences
Science China Earth Sciences GEOSCIENCES, MULTIDISCIPLINARY-
CiteScore
9.60
自引率
5.30%
发文量
135
审稿时长
3-8 weeks
期刊介绍: Science China Earth Sciences, an academic journal cosponsored by the Chinese Academy of Sciences and the National Natural Science Foundation of China, and published by Science China Press, is committed to publishing high-quality, original results in both basic and applied research.
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