天气预报时空预报技术案例研究

IF 2.2 4区 计算机科学 Q3 COMPUTER SCIENCE, INFORMATION SYSTEMS Geoinformatica Pub Date : 2024-09-14 DOI:10.1007/s10707-024-00530-y
Shakir Showkat Sofi, Ivan Oseledets
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引用次数: 0

摘要

现实世界中的大多数过程都是时空过程,由其产生的数据同时表现出空间和时间的演变。天气是这一领域中最重要的过程之一,天气预报已成为我们日常工作的重要组成部分。天气数据分析被认为是最复杂、最具挑战性的任务。尽管数值天气预报模型是目前最先进的模型,但它们需要耗费大量资源和时间。许多研究提出了基于时间序列的模型,作为数值预报的可行替代方案。时间序列分析领域的最新研究表明,该领域取得了重大进展,尤其是在使用基于状态空间的模型(白盒)方面,以及最近在整合机器学习和基于深度神经网络的模型(黑盒)方面。此类模型最著名的例子是 RNN 和变压器。这些模型在时间序列分析领域取得了令人瞩目的成果,并在时间相关性建模方面显示出了有效性。对于时空过程来说,捕捉时间和空间相关性至关重要,因为附近地点和时间的值会影响特定点的时空过程值。这篇自成一体的论文探讨了各种区域数据驱动天气预报方法,即在多个经纬度点(矩阵形空间网格)上进行预报,以捕捉时空相关性。结果表明,时空预测模型降低了计算成本,同时提高了准确性。特别是,所提出的基于张量列车动态模式分解的预测模型无需训练,其准确度与最先进的模型相当。我们提供了令人信服的数值实验,证明所提出的方法切实可行。
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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A case study of spatiotemporal forecasting techniques for weather forecasting

The majority of real-world processes are spatiotemporal, and the data generated by them exhibits both spatial and temporal evolution. Weather is one of the most essential processes in this domain, and weather forecasting has become a crucial part of our daily routine. Weather data analysis is considered the most complex and challenging task. Although numerical weather prediction models are currently state-of-the-art, they are resource-intensive and time-consuming. Numerous studies have proposed time series-based models as a viable alternative to numerical forecasts. Recent research in the area of time series analysis indicates significant advancements, particularly regarding the use of state-space-based models (white box) and, more recently, the integration of machine learning and deep neural network-based models (black box). The most famous examples of such models are RNNs and transformers. These models have demonstrated remarkable results in the field of time-series analysis and have demonstrated effectiveness in modelling temporal correlations. It is crucial to capture both temporal and spatial correlations for a spatiotemporal process, as the values at nearby locations and time affect the values of a spatiotemporal process at a specific point. This self-contained paper explores various regional data-driven weather forecasting methods, i.e., forecasting over multiple latitude-longitude points (matrix-shaped spatial grid) to capture spatiotemporal correlations. The results showed that spatiotemporal prediction models reduced computational costs while improving accuracy. In particular, the proposed tensor train dynamic mode decomposition-based forecasting model has comparable accuracy to the state-of-the-art models without the need for training. We provide convincing numerical experiments to show that the proposed approach is practical.

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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.
期刊最新文献
LENS: label sparsity-tolerant adversarial learning on spatial deceptive reviews A case study of spatiotemporal forecasting techniques for weather forecasting CLMTR: a generic framework for contrastive multi-modal trajectory representation learning Periodicity aware spatial-temporal adaptive hypergraph neural network for traffic forecasting ICN: Interactive convolutional network for forecasting travel demand of shared micromobility
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