DGFormer:采用动态时空图神经网络的物理学指导台站级天气预报模型

IF 2.2 4区 计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS
Zhewen Xu, Xiaohui Wei, Jieyun Hao, Junze Han, Hongliang Li, Changzheng Liu, Zijian Li, Dongyuan Tian, Nong Zhang
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引用次数: 0

摘要

近年来,人们越来越关注利用空间-时间图神经网络(STGNN)来理解和预测气象站数据。然而,由于其固有的非线性和动态时空自相关性的影响,其预测误差较大。按时间顺序使用连续变化的图拓扑,同时嵌入领域知识以加强有效性,可以有效地解决这一问题,但这一概念的实现对研究人员来说是一个跨学科的挑战。为应对这一挑战,我们提出了一种动态图形成器(DGFormer)模型。它通过深度生成层将拓扑学习器与插入 STGNN 结构的领域知识增强相结合,其中衍生的物理引导方法允许与地球系统高效集成。为了捕捉最佳拓扑结构,我们将基于节点嵌入的相似度量学习和叠加原理作为物理辅助工具融入动态图模块。我们利用真实世界的天气数据集对我们的模型进行了短期(12 小时)和中期(360 小时)预测任务的评估。与最先进的方法相比,DGFormer 在短期预测和中程预测方面分别取得了 34.84% 和 23.25% 的明显改善,表现出色。我们还对三个地区的城市进行了详细分析,并将动态图可视化,从而揭示了我们模型的特点、优势和图形可视化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

DGFormer: a physics-guided station level weather forecasting model with dynamic spatial-temporal graph neural network

DGFormer: a physics-guided station level weather forecasting model with dynamic spatial-temporal graph neural network

In recent years, there has been an increased interest in understanding and predicting the weather using weather station data with Spatial-Temporal Graph Neural Networks (STGNN). However, it has large prediction errors as a result of the inherent non-linearities and the influence of dynamic spatio-temporal auto-correlation. Using a continuously-varying graph topology chronologically, while embedding domain knowledge to enforce validity, can effectively resolve the issue, but the implementation of such concept constitutes an interdisciplinary challenge for researchers. A Dynamic Graph Former (DGFormer) model is proposed to address this challenge. It combines a topology learner through a deep generative layer with domain knowledge enhancement inserted into the STGNN structure, where the derived physics-guided method allows for an efficient integration with the earth system. For capture of the optimal topology, we merge a node-embedding-based similarity metric learning and the superposition principle as physical assistants into the dynamic graph module. We evaluate our model with a real-world weather dataset on short-term (12 hours) and medium-range (360 hours) prediction tasks. DGFormer achieves outstanding performance with obvious improvements by up to 34.84% at short-term prediction and by up to 23.25% at medium-range prediction compared with the state-of-the-art methods. We also conducted detailed analyses for cities in three regions and visualized the dynamic graph, revealing the characteristics, advantages, and graph visualization of our model.

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来源期刊
Geoinformatica
Geoinformatica 地学-计算机:信息系统
CiteScore
5.60
自引率
10.00%
发文量
25
审稿时长
6 months
期刊介绍: GeoInformatica is located at the confluence of two rapidly advancing domains: Computer Science and Geographic Information Science; nowadays, Earth studies use more and more sophisticated computing theory and tools, and computer processing of Earth observations through Geographic Information Systems (GIS) attracts a great deal of attention from governmental, industrial and research worlds. This journal aims to promote the most innovative results coming from the research in the field of computer science applied to geographic information systems. Thus, GeoInformatica provides an effective forum for disseminating original and fundamental research and experience in the rapidly advancing area of the use of computer science for spatial studies.
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