Multistage Graph Convolutional Network With Spatial Attention for Multivariate Time Series Imputation.

IF 10.2 1区 计算机科学 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE IEEE transactions on neural networks and learning systems Pub Date : 2024-11-06 DOI:10.1109/TNNLS.2024.3486349
Qianyi Chen, Jiannong Cao, Yu Yang, Wanyu Lin, Sumei Wang, Youwu Wang
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Abstract

In multivariate time series (MTS) analysis, data loss is a critical issue that degrades analytical model performance and impairs downstream tasks such as structural health monitoring (SHM) and traffic flow monitoring. In real-world applications, MTS is usually collected by multiple types of sensors, making MTS and correlations between variates heterogeneous. However, existing MTS imputation methods overlook the heterogeneous correlations by manipulating heterogeneous MTS as a homogeneous entity, leading to inaccurate imputation results. Besides, correlations between different data types vary due to ever-changing environmental conditions, forming dynamic correlations in MTS. How to properly learn the hidden correlation from heterogeneous MTS for accurate data imputation remains unresolved. To solve the problem, we propose a multistage graph convolutional network with spatial attention (MSA-GCN). In the first stage, we decompose heterogeneous MTS into several clusters with homogeneous data collected from identical sensor types and learn intracluster correlations. Then, we devise a GCN with spatial attention to explore dynamic intercluster correlations, which is the second stage of MSA-GCN. In the last stage, we decode the learned features from previous stages via stacked convolutional neural networks. We jointly train these three-stage models to predict the missing data in MTS. Leveraging this multistage architecture and spatial attention mechanism makes MSA-GCN effectively learn heterogeneous and dynamic correlations among MTS, resulting in superior imputation performance. We tested MSA-GCN with the monitoring data from a large-span bridge and Wetterstation weather dataset. The results affirm its superiority over baseline models, demonstrating its enhanced accuracy in reducing imputation errors across diverse datasets.

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多级图卷积网络与多变量时间序列推算的空间注意力
在多变量时间序列(MTS)分析中,数据丢失是一个关键问题,它会降低分析模型的性能,并影响结构健康监测(SHM)和交通流监测等下游任务。在实际应用中,MTS 通常由多种类型的传感器收集,这使得 MTS 和变量之间的相关性具有异质性。然而,现有的 MTS 估算方法将异构 MTS 作为同构实体处理,从而忽略了异构相关性,导致估算结果不准确。此外,不同数据类型之间的相关性会因环境条件的不断变化而变化,从而在 MTS 中形成动态相关性。如何从异构 MTS 中正确地学习隐藏的相关性,以获得准确的数据估算结果,仍是一个悬而未决的问题。为了解决这个问题,我们提出了一种具有空间注意力的多级图卷积网络(MSA-GCN)。在第一阶段,我们将异构 MTS 分解成几个具有从相同传感器类型收集的同质数据的簇,并学习簇内相关性。然后,我们设计一个具有空间注意力的 GCN,以探索集群间的动态相关性,这是 MSA-GCN 的第二阶段。在最后一个阶段,我们通过堆叠卷积神经网络对前几个阶段学习到的特征进行解码。我们联合训练这三个阶段的模型,以预测 MTS 中的缺失数据。利用这种多级架构和空间关注机制,MSA-GCN 可以有效地学习 MTS 之间的异构动态相关性,从而实现出色的归因性能。我们用一座大跨度桥梁的监测数据和 Wetterstation 气象数据集测试了 MSA-GCN。结果表明 MSA-GCN 优于基线模型,在减少不同数据集的归因误差方面具有更高的准确性。
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来源期刊
IEEE transactions on neural networks and learning systems
IEEE transactions on neural networks and learning systems COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-COMPUTER SCIENCE, HARDWARE & ARCHITECTURE
CiteScore
23.80
自引率
9.60%
发文量
2102
审稿时长
3-8 weeks
期刊介绍: The focus of IEEE Transactions on Neural Networks and Learning Systems is to present scholarly articles discussing the theory, design, and applications of neural networks as well as other learning systems. The journal primarily highlights technical and scientific research in this domain.
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