Stochastic Block Model-Aware Topological Neural Networks for Graph Link Prediction
Abstract: Link prediction is an important learning task for graph-structured data and is indispensable to understanding graphs' properties. Recent works focus on designing complicated graph neural networks (GNNs) architectures to explore and capture various pairwise interactions among graph nodes. Most GNNs are based on combining graph structural and node feature information by iterative message-passing schemes. However, despite GNNs revolutionizing the field of graph representation learning, some thorny questions are raised concerning whether GNNs can efficiently learn the edge probabilities based on topological structures (i.e., higher-order interactions) and node features, and provide statistically rigorous uncertainty estimates. In this paper, we tackle these challenges and propose a novel stochastic block model (SBM)-aware topological neural networks, called SBM-TNN, that uses SBMs to infer the latent community structure of nodes from graph structures and uses persistent homology to encode higher-order information. Furthermore, we theoretically study the entrywise bound and asymptotic normality of the estimated edge probability matrix to quantify the uncertainty in statistical inference of the edge probabilities. Our extensive experiments for link prediction on both graphs and knowledge graphs show that SBM-TNN achieves state-of-the-art performance over a set of popular baseline methods.
Submission Length: Regular submission (no more than 12 pages of main content)
Assigned Action Editor: ~Zhangyang_Wang1
Submission Number: 4615
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