概率误差模型下的图卷积神经网络灵敏度

IF 3 3区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

IEEE Transactions on Signal and Information Processing over Networks Pub Date : 2024-10-23 DOI:10.1109/TSIPN.2024.3485532

Xinjue Wang;Esa Ollila;Sergiy A. Vorobyov

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引用次数: 0

摘要

图神经网络（GNN），尤其是图卷积神经网络（GCNN），已成为机器学习和信号处理领域处理图结构数据的重要工具。本文提出了一个分析框架，用于研究 GCNN 对直接影响图移动算子（GSO）的概率图扰动的敏感性。我们的研究建立了与误差模型参数明确相关的严格预期 GSO 误差边界，并揭示了 GSO 扰动与 GCNN 各层输出差异之间的线性关系。这种线性关系表明，单层 GCNN 在图边扰动下仍能保持稳定，前提是 GSO 误差保持在一定范围内，而与扰动规模无关。对于多层 GCNN，系统输出差值对 GSO 扰动的依赖性被证明是线性递归。最后，我们用图同构网络（GIN）和简单图卷积网络（SGCN）举例说明了这一框架。实验验证了我们的理论推导和方法的有效性。

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Graph Convolutional Neural Networks Sensitivity Under Probabilistic Error Model

Graph Neural Networks (GNNs), particularly Graph Convolutional Neural Networks (GCNNs), have emerged as pivotal instruments in machine learning and signal processing for processing graph-structured data. This paper proposes an analysis framework to investigate the sensitivity of GCNNs to probabilistic graph perturbations, directly impacting the graph shift operator (GSO). Our study establishes tight expected GSO error bounds, which are explicitly linked to the error model parameters, and reveals a linear relationship between GSO perturbations and the resulting output differences at each layer of GCNNs. This linearity demonstrates that a single-layer GCNN maintains stability under graph edge perturbations, provided that the GSO errors remain bounded, regardless of the perturbation scale. For multilayer GCNNs, the dependency of system's output difference on GSO perturbations is shown to be a recursion of linearity. Finally, we exemplify the framework with the Graph Isomorphism Network (GIN) and Simple Graph Convolution Network (SGCN). Experiments validate our theoretical derivations and the effectiveness of our approach.

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来源期刊

IEEE Transactions on Signal and Information Processing over Networks Computer Science-Computer Networks and Communications

CiteScore

5.80

自引率

12.50%

发文量

期刊介绍： The IEEE Transactions on Signal and Information Processing over Networks publishes high-quality papers that extend the classical notions of processing of signals defined over vector spaces (e.g. time and space) to processing of signals and information (data) defined over networks, potentially dynamically varying. In signal processing over networks, the topology of the network may define structural relationships in the data, or may constrain processing of the data. Topics include distributed algorithms for filtering, detection, estimation, adaptation and learning, model selection, data fusion, and diffusion or evolution of information over such networks, and applications of distributed signal processing.