Litcius/Paper detail

How does Heterophily Impact the Robustness of Graph Neural Networks?

Jiong Zhu, Junchen Jin, Donald Loveland, Michael T. Schaub, Danai Koutra

2022Proceedings of the 28th ACM SIGKDD Conference on Knowledge Discovery and Data Mining26 citationsDOIOpen Access PDF

Abstract

We bridge two research directions on graph neural networks (GNNs), by formalizing the relation between heterophily of node labels (i.e., connected nodes tend to have dissimilar labels) and the robustness of GNNs to adversarial attacks. Our theoretical and empirical analyses show that for homophilous graph data, impactful structural attacks always lead to reduced homophily, while for heterophilous graph data the change in the homophily level depends on the node degrees. These insights have practical implications for defending against attacks on real-world graphs: we deduce that separate aggregators for ego- and neighbor-embeddings, a design principle which has been identified to significantly improve prediction for heterophilous graph data, can also offer increased robustness to GNNs. Our comprehensive experiments show that GNNs merely adopting this design achieve improved empirical and certifiable robustness compared to the best-performing unvaccinated model. Additionally, combining this design with explicit defense mechanisms against adversarial attacks leads to an improved robustness with up to 18.33% performance increase under attacks compared to the best-performing vaccinated model.

Topics & Concepts

HomophilyComputer scienceRobustness (evolution)Theoretical computer scienceAdversarial systemGraphMachine learningEmpirical researchArtificial neural networkArtificial intelligenceData miningMathematicsStatisticsCombinatoricsGeneChemistryBiochemistryAdvanced Graph Neural NetworksComplex Network Analysis Techniques