多层网络聚类的图形对比学习

IF 7.5 3区计算机科学 Q1 COMPUTER SCIENCE, INFORMATION SYSTEMS

IEEE Transactions on Big Data Pub Date : 2023-12-14 DOI:10.1109/TBDATA.2023.3343349

Yifei Yang;Xiaoke Ma

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引用次数: 0

摘要

多层网络可以精确地模拟社会和自然界中具有各种相互作用的复杂系统，而识别各层中连接良好的保守模块对于揭示其结构-功能关系具有重要意义。目前的算法要么忽略了各层之间的内在关系，要么无法学习到辨别特征，因而饱受诟病。为了解决这些局限性，我们提出了一种用于多层网络聚类的新型图对比学习框架，将非负矩阵因式分解和图对比学习结合起来（称为 jNMF-GCL），同时解决固有结构和特征的判别问题。具体来说，首先通过矩阵因式分解保留多层网络中的守恒结构来学习顶点特征，然后 jNMF-GCL 通过处理各层特征来学习顶点的亲和结构。为了提高特征的质量，jNMF-GCL 通过从构建的亲和图中选择正样本和负样本来执行对比学习，这大大提高了特征的判别能力。最后，jNMF-GCL 将特征学习、亲和图构建、对比学习和聚类整合为一个整体目标，将全局和局部结构信息无缝融合，为描述多层网络结构提供了一种更有效的方法。在人工网络和真实世界网络上进行的大量实验表明，jNMF-GCL 在各种指标上都优于最先进的模型。

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Graph Contrastive Learning for Clustering of Multi-Layer Networks

Multi-layer networks precisely model complex systems in society and nature with various types of interactions, and identifying conserved modules that are well-connected in all layers is of great significance for revealing their structure-function relationships. Current algorithms are criticized for either ignoring the intrinsic relations among various layers, or failing to learn discriminative features. To attack these limitations, a novel graph contrastive learning framework for clustering of multi-layer networks is proposed by joining nonnegative matrix factorization and graph contrastive learning (called jNMF-GCL), where the intrinsic structure and discriminative of features are simultaneously addressed. Specifically, features of vertices are first learned by preserving the conserved structure in multi-layer networks with matrix factorization, and then jNMF-GCL learns an affinity structure of vertices by manipulating features of various layers. To enhance quality of features, contrastive learning is executed by selecting the positive and negative samples from the constructed affinity graph, which significantly improves discriminative of features. Finally, jNMF-GCL incorporates feature learning, construction of affinity graph, contrastive learning and clustering into an overall objective, where global and local structural information are seamlessly fused, providing a more effective way to describe structure of multi-layer networks. Extensive experiments conducted on both artificial and real-world networks have shown the superior performance of jNMF-GCL over state-of-the-art models across various metrics.

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来源期刊

IEEE Transactions on Big Data Multiple-

CiteScore

11.80

自引率

2.80%

发文量

114

期刊介绍： The IEEE Transactions on Big Data publishes peer-reviewed articles focusing on big data. These articles present innovative research ideas and application results across disciplines, including novel theories, algorithms, and applications. Research areas cover a wide range, such as big data analytics, visualization, curation, management, semantics, infrastructure, standards, performance analysis, intelligence extraction, scientific discovery, security, privacy, and legal issues specific to big data. The journal also prioritizes applications of big data in fields generating massive datasets.