DisenSemi: Semi-supervised Graph Classification via Disentangled Representation Learning
- URL: http://arxiv.org/abs/2407.14081v2
- Date: Fri, 9 Aug 2024 08:23:12 GMT
- Title: DisenSemi: Semi-supervised Graph Classification via Disentangled Representation Learning
- Authors: Yifan Wang, Xiao Luo, Chong Chen, Xian-Sheng Hua, Ming Zhang, Wei Ju,
- Abstract summary: We propose a novel framework named DisenSemi, which learns disentangled representation for semi-supervised graph classification.
Specifically, a disentangled graph encoder is proposed to generate factor-wise graph representations for both supervised and unsupervised models.
We train two models via supervised objective and mutual information (MI)-based constraints respectively.
- Score: 36.85439684013268
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Graph classification is a critical task in numerous multimedia applications, where graphs are employed to represent diverse types of multimedia data, including images, videos, and social networks. Nevertheless, in real-world scenarios, labeled graph data can be limited or scarce. To address this issue, we focus on the problem of semi-supervised graph classification, which involves both supervised and unsupervised models learning from labeled and unlabeled data. In contrast to recent approaches that transfer the entire knowledge from the unsupervised model to the supervised one, we argue that an effective transfer should only retain the relevant semantics that align well with the supervised task. In this paper, we propose a novel framework named DisenSemi, which learns disentangled representation for semi-supervised graph classification. Specifically, a disentangled graph encoder is proposed to generate factor-wise graph representations for both supervised and unsupervised models. Then we train two models via supervised objective and mutual information (MI)-based constraints respectively. To ensure the meaningful transfer of knowledge from the unsupervised encoder to the supervised one, we further define an MI-based disentangled consistency regularization between two models and identify the corresponding rationale that aligns well with the current graph classification task. Experimental results on a range of publicly accessible datasets reveal the effectiveness of our DisenSemi.
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