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Auteurs principaux: Mendelman, Harel, Maron, Haggai, Talmon, Ronen
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2505.12411
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author Mendelman, Harel
Maron, Haggai
Talmon, Ronen
author_facet Mendelman, Harel
Maron, Haggai
Talmon, Ronen
contents Graph Neural Networks (GNNs) excel at analyzing graph-structured data but struggle on heterophilic graphs, where connected nodes often belong to different classes. While this challenge is commonly addressed with specialized GNN architectures, graph rewiring remains an underexplored strategy in this context. We provide theoretical foundations linking edge homophily, GNN embedding smoothness, and node classification performance, motivating the need to enhance homophily. Building on this insight, we introduce a rewiring framework that increases graph homophily using a reference graph, with theoretical guarantees on the homophily of the rewired graph. To broaden applicability, we propose a label-driven diffusion approach for constructing a homophilic reference graph from node features and training labels. Through extensive simulations, we analyze how the homophily of both the original and reference graphs influences the rewired graph homophily and downstream GNN performance. We evaluate our method on 11 real-world heterophilic datasets and show that it outperforms existing rewiring techniques and specialized GNNs for heterophilic graphs, achieving improved node classification accuracy while remaining efficient and scalable to large graphs.
format Preprint
id arxiv_https___arxiv_org_abs_2505_12411
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle It Takes a Graph to Know a Graph: Rewiring for Homophily with a Reference Graph
Mendelman, Harel
Maron, Haggai
Talmon, Ronen
Machine Learning
Graph Neural Networks (GNNs) excel at analyzing graph-structured data but struggle on heterophilic graphs, where connected nodes often belong to different classes. While this challenge is commonly addressed with specialized GNN architectures, graph rewiring remains an underexplored strategy in this context. We provide theoretical foundations linking edge homophily, GNN embedding smoothness, and node classification performance, motivating the need to enhance homophily. Building on this insight, we introduce a rewiring framework that increases graph homophily using a reference graph, with theoretical guarantees on the homophily of the rewired graph. To broaden applicability, we propose a label-driven diffusion approach for constructing a homophilic reference graph from node features and training labels. Through extensive simulations, we analyze how the homophily of both the original and reference graphs influences the rewired graph homophily and downstream GNN performance. We evaluate our method on 11 real-world heterophilic datasets and show that it outperforms existing rewiring techniques and specialized GNNs for heterophilic graphs, achieving improved node classification accuracy while remaining efficient and scalable to large graphs.
title It Takes a Graph to Know a Graph: Rewiring for Homophily with a Reference Graph
topic Machine Learning
url https://arxiv.org/abs/2505.12411