A Generic Framework for Interesting Subspace Cluster Detection in Multi-attributed Networks

TL;DR

This paper introduces a generic, efficient, and theoretically guaranteed framework for detecting interesting subspace clusters in large multi-attributed networks, addressing a gap in existing methods.

Contribution

We propose SG-Pursuit, a subspace graph-structured matching pursuit algorithm with rigorous guarantees, capable of detecting various types of subspace clusters in multi-attributed networks.

Findings

SG-Pursuit runs in nearly-linear time relative to network size and attributes.

The algorithm provides geometric convergence and tight error bounds.

Empirical results show SG-Pursuit outperforms state-of-the-art methods in real-world tasks.

Abstract

Detection of interesting (e.g., coherent or anomalous) clusters has been studied extensively on plain or univariate networks, with various applications. Recently, algorithms have been extended to networks with multiple attributes for each node in the real-world. In a multi-attributed network, often, a cluster of nodes is only interesting for a subset (subspace) of attributes, and this type of clusters is called subspace clusters. However, in the current literature, few methods are capable of detecting subspace clusters, which involves concurrent feature selection and network cluster detection. These relevant methods are mostly heuristic-driven and customized for specific application scenarios. In this work, we present a generic and theoretical framework for detection of interesting subspace clusters in large multi-attributed networks. Specifically, we propose a subspace graph-structured matching pursuit algorithm, namely, SG-Pursuit, to address a broad class of such problems for different score functions (e.g., coherence or anomalous functions) and topology constraints (e.g., connected subgraphs and dense subgraphs). We prove that our algorithm 1) runs in nearly-linear time on the network size and the total number of attributes and 2) enjoys rigorous guarantees (geometrical convergence rate and tight error bound) analogous to those of the state-of-the-art algorithms for sparse feature selection problems and subgraph detection problems. As a case study, we specialize SG-Pursuit to optimize a number of well-known score functions for two typical tasks, including detection of coherent dense and anomalous connected subspace clusters in real-world networks. Empirical evidence demonstrates that our proposed generic algorithm SG-Pursuit performs superior over state-of-the-art methods that are designed specifically for these two tasks.