Hyperedge Modeling in Hypergraph Neural Networks by using Densest Overlapping Subgraphs

arXiv - CS - Social and Information Networks Pub Date : 2024-09-16 DOI:arxiv-2409.10340

Mehrad Soltani, Luis Rueda

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Abstract

Hypergraphs tackle the limitations of traditional graphs by introducing {\em hyperedges}. While graph edges connect only two nodes, hyperedges connect an arbitrary number of nodes along their edges. Also, the underlying message-passing mechanisms in Hypergraph Neural Networks (HGNNs) are in the form of vertex-hyperedge-vertex, which let HGNNs capture and utilize richer and more complex structural information than traditional Graph Neural Networks (GNNs). More recently, the idea of overlapping subgraphs has emerged. These subgraphs can capture more information about subgroups of vertices without limiting one vertex belonging to just one group, allowing vertices to belong to multiple groups or subgraphs. In addition, one of the most important problems in graph clustering is to find densest overlapping subgraphs (DOS). In this paper, we propose a solution to the DOS problem via Agglomerative Greedy Enumeration (DOSAGE) algorithm as a novel approach to enhance the process of generating the densest overlapping subgraphs and, hence, a robust construction of the hypergraphs. Experiments on standard benchmarks show that the DOSAGE algorithm significantly outperforms the HGNNs and six other methods on the node classification task.

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利用最密集重叠子图在超图神经网络中建立超edge 模型

超图通过引入{emhyperedges}解决了传统图的局限性。图的边只连接两个节点，而超图则沿边连接任意数量的节点。此外，超图神经网络（HGNN）的基本信息传递机制是顶点-超边-顶点的形式，这使得 HGNN 能够捕捉和利用比传统图神经网络（GNN）更丰富、更复杂的结构信息。最近，出现了重叠子图的概念。这些子图可以捕捉更多的顶点子群信息，而不会限制一个顶点只属于一个群组，从而允许顶点属于多个群组或子图。此外，图聚类中最重要的问题之一是找到最密集的重叠子图（DOS）。在本文中，我们提出了一种通过聚合贪婪枚举（Agglomerative GreedyEnumeration，简称 "DABA"）算法解决 DOS 问题的方法，这是一种新颖的方法，可以增强最密集重叠子图的生成过程，从而稳健地构建超图。在标准基准上进行的实验表明，在节点分类任务上，该算法明显优于 HGNN 和其他六种方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - CS - Social and Information Networks

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