基于优化的图粗化统一框架

Manoj Kumar, Anurag Sharma, Surinder Kumar
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引用次数: 1

摘要

图粗化是一种广泛应用于处理大规模图机器学习问题的降维技术。给定一个大的图,图粗化的目的是学习一个更小的易于处理的图,同时保留原给定图的性质。图数据由节点特征和图矩阵(如邻接矩阵和拉普拉斯矩阵)组成。现有的图粗化方法忽略了节点特征,仅依靠图矩阵来简化图。本文提出了一种新的基于优化的图降维框架。提出的框架是图学习和降维的统一。它以图矩阵和节点特征作为输入,在保证所需性质的前提下,联合学习粗图矩阵和粗特征矩阵。所提出的优化公式是一个多块非凸优化问题,该问题通过利用块最大化最小化、$\log$行列式、狄利克雷能量和正则化框架有效地解决。所提出的算法收敛性好,适用于多种任务。并证明了学习后的粗化图与原始图$\epsilon\in(0,1)$相似。大量的实验阐明了所提出的框架在实际应用中的有效性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A Unified Framework for Optimization-Based Graph Coarsening
Graph coarsening is a widely used dimensionality reduction technique for approaching large-scale graph machine learning problems. Given a large graph, graph coarsening aims to learn a smaller-tractable graph while preserving the properties of the originally given graph. Graph data consist of node features and graph matrix (e.g., adjacency and Laplacian). The existing graph coarsening methods ignore the node features and rely solely on a graph matrix to simplify graphs. In this paper, we introduce a novel optimization-based framework for graph dimensionality reduction. The proposed framework lies in the unification of graph learning and dimensionality reduction. It takes both the graph matrix and the node features as the input and learns the coarsen graph matrix and the coarsen feature matrix jointly while ensuring desired properties. The proposed optimization formulation is a multi-block non-convex optimization problem, which is solved efficiently by leveraging block majorization-minimization, $\log$ determinant, Dirichlet energy, and regularization frameworks. The proposed algorithms are provably convergent and practically amenable to numerous tasks. It is also established that the learned coarsened graph is $\epsilon\in(0,1)$ similar to the original graph. Extensive experiments elucidate the efficacy of the proposed framework for real-world applications.
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