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Towards Faithful and Consistent Explanations for Graph Neural Networks

Tianxiang Zhao, Dongsheng Luo, X. D. Zhang, Suhang Wang

202313 citationsDOI

Abstract

Uncovering rationales behind predictions of graph neural networks (GNNs) has received increasing attention over recent years. Instance-level GNN explanation aims to discover critical input elements, like nodes or edges, that the target GNN relies upon for making predictions. Though various algorithms are proposed, most of them formalize this task by searching the minimal subgraph which can preserve original predictions. However, an inductive bias is deep-rooted in this framework: several subgraphs can result in the same or similar outputs as the original graphs. Consequently, they have the danger of providing spurious explanations and fail to provide consistent explanations. Applying them to explain weakly-performed GNNs would further amplify these issues. To address this problem, we theoretically examine the predictions of GNNs from the causality perspective. Two typical reasons of spurious explanations are identified: confounding effect of latent variables like distribution shift, and causal factors distinct from the original input. Observing that both confounding effects and diverse causal rationales are encoded in internal representations, we propose a simple yet effective countermeasure by aligning embeddings. Concretely, concerning potential shifts in the high-dimensional space, we design a distribution-aware alignment algorithm based on anchors. This new objective is easy to compute and can be incorporated into existing techniques with no or little effort. Theoretical analysis shows that it is in effect optimizing a more faithful explanation objective in design, which further justifies the proposed approach.

Topics & Concepts

Spurious relationshipComputer scienceCausality (physics)Perspective (graphical)GraphTheoretical computer scienceArtificial intelligenceSimple (philosophy)Task (project management)Machine learningEpistemologyPhilosophyPhysicsQuantum mechanicsEconomicsManagementExplainable Artificial Intelligence (XAI)Advanced Graph Neural NetworksMachine Learning in Materials Science