English

Towards Higher-order Topological Consistency for Unsupervised Network Alignment

Machine Learning 2022-08-29 v1 Social and Information Networks

Abstract

Network alignment task, which aims to identify corresponding nodes in different networks, is of great significance for many subsequent applications. Without the need for labeled anchor links, unsupervised alignment methods have been attracting more and more attention. However, the topological consistency assumptions defined by existing methods are generally low-order and less accurate because only the edge-indiscriminative topological pattern is considered, which is especially risky in an unsupervised setting. To reposition the focus of the alignment process from low-order to higher-order topological consistency, in this paper, we propose a fully unsupervised network alignment framework named HTC. The proposed higher-order topological consistency is formulated based on edge orbits, which is merged into the information aggregation process of a graph convolutional network so that the alignment consistencies are transformed into the similarity of node embeddings. Furthermore, the encoder is trained to be multi-orbit-aware and then be refined to identify more trusted anchor links. Node correspondence is comprehensively evaluated by integrating all different orders of consistency. {In addition to sound theoretical analysis, the superiority of the proposed method is also empirically demonstrated through extensive experimental evaluation. On three pairs of real-world datasets and two pairs of synthetic datasets, our HTC consistently outperforms a wide variety of unsupervised and supervised methods with the least or comparable time consumption. It also exhibits robustness to structural noise as a result of our multi-orbit-aware training mechanism.

Keywords

Cite

@article{arxiv.2208.12463,
  title  = {Towards Higher-order Topological Consistency for Unsupervised Network Alignment},
  author = {Qingqiang Sun and Xuemin Lin and Ying Zhang and Wenjie Zhang and Chaoqi Chen},
  journal= {arXiv preprint arXiv:2208.12463},
  year   = {2022}
}

Comments

Accepted by IEEE International Conference on Data Engineering (ICDE), 2023

R2 v1 2026-06-25T01:59:39.599Z