Robust Deep Signed Graph Clustering via Weak Balance Theory

TL;DR

This paper introduces DSGC, a robust deep signed graph clustering framework that leverages Weak Balance Theory to improve noise resilience and cluster boundary accuracy in signed graph data.

Contribution

The paper proposes a novel DSGC framework that incorporates Weak Balance Theory for denoising, augmentation, and clustering, advancing signed graph clustering methods.

Findings

Outperforms existing methods on synthetic datasets

Achieves state-of-the-art results on real-world datasets

Demonstrates robustness to noise and improved cluster boundaries

Abstract

Signed graph clustering is a critical technique for discovering community structures in graphs that exhibit both positive and negative relationships. We have identified two significant challenges in this domain: i) existing signed spectral methods are highly vulnerable to noise, which is prevalent in real-world scenarios; ii) the guiding principle ``an enemy of my enemy is my friend'', rooted in \textit{Social Balance Theory}, often narrows or disrupts cluster boundaries in mainstream signed graph neural networks. Addressing these challenges, we propose the \underline{D}eep \underline{S}igned \underline{G}raph \underline{C}lustering framework (DSGC), which leverages \textit{Weak Balance Theory} to enhance preprocessing and encoding for robust representation learning. First, DSGC introduces Violation Sign-Refine to denoise the signed network by correcting noisy edges with high-order neighbor information. Subsequently, Density-based Augmentation enhances semantic structures by adding positive edges within clusters and negative edges across clusters, following \textit{Weak Balance} principles. The framework then utilizes \textit{Weak Balance} principles to develop clustering-oriented signed neural networks to broaden cluster boundaries by emphasizing distinctions between negatively linked nodes. Finally, DSGC optimizes clustering assignments by minimizing a regularized clustering loss. Comprehensive experiments on synthetic and real-world datasets demonstrate DSGC consistently outperforms all baselines, establishing a new benchmark in signed graph clustering.