PSMC: Provable and Scalable Algorithms for Motif Conductance Based Graph Clustering

Longlong Lin, Tao Jia, Zeli Wang, Jin Zhao, Rong-Hua Li
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Abstract

Higher-order graph clustering aims to partition the graph using frequently occurring subgraphs. Motif conductance is one of the most promising higher-order graph clustering models due to its strong interpretability. However, existing motif conductance based graph clustering algorithms are mainly limited by a seminal two-stage reweighting computing framework, needing to enumerate all motif instances to obtain an edge-weighted graph for partitioning. However, such a framework has two-fold vital defects: (1) It can only provide a quadratic bound for the motif with three vertices, and whether there is provable clustering quality for other motifs is still an open question. (2) The enumeration procedure of motif instances incurs prohibitively high costs against large motifs or large dense graphs due to combinatorial explosions. Besides, expensive spectral clustering or local graph diffusion on the edge-weighted graph also makes existing methods unable to handle massive graphs with millions of nodes. To overcome these dilemmas, we propose a Provable and Scalable Motif Conductance algorithm PSMC, which has a fixed and motif-independent approximation ratio for any motif. Specifically, PSMC first defines a new vertex metric Motif Resident based on the given motif, which can be computed locally. Then, it iteratively deletes the vertex with the smallest motif resident value very efficiently using novel dynamic update technologies. Finally, it outputs the locally optimal result during the above iterative process. To further boost efficiency, we propose several effective bounds to estimate the motif resident value of each vertex, which can greatly reduce computational costs. Empirical results show that our proposed algorithms achieve 3.2-32 times speedup and improve the quality by at least 12 times than the baselines.
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PSMC:基于动机传导的图形聚类的可证明和可扩展算法
高阶图聚类旨在利用经常出现的子图对图进行划分。然而,现有的基于图案传导的图聚类算法主要受限于一个开创性的两阶段加权计算框架,即需要枚举所有图案实例以获得一个边加权图来进行划分。然而,这样的框架有两个重要缺陷:(1)它只能为有三个顶点的图案提供二次约束,而对于其他图案是否有可证明的聚类质量仍是一个未决问题。(2)由于组合爆炸,对大型图案或大型密集图来说,图案实例的枚举过程会产生过高的成本。此外,在边缘加权图上进行昂贵的谱聚类或局部图扩散也使得现有方法无法处理数百万节点的大型图。为了克服这些难题,我们提出了一种可预测和可扩展的图案传导算法 PSMC,它对任何图案都有固定的、与图案无关的近似率。具体来说,PSMC 首先根据给定的图案定义一个新的顶点度量 Motif Resident,该度量可在本地计算。然后,它利用新颖的动态更新技术,非常高效地迭代删除 Motif Resident 值最小的顶点。最后,它输出上述迭代过程中的局部最优结果。为了进一步提高效率,我们提出了几个有效的边界来估计每个顶点的图案驻留值,这可以大大降低计算成本。实证结果表明,我们提出的算法速度提高了 3.2-32 倍,质量提高了至少 12 倍。
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