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Evaluating explainability for graph neural networks.

Chirag Agarwal1,2, Owen Queen2,3, Himabindu Lakkaraju4,5,6

  • 1Media and Data Science Research Lab, Adobe, Noida, 201304, India.

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Summary
This summary is machine-generated.

Evaluating graph neural network (GNN) explanations is vital but difficult. We introduce SHAPEGGEN for synthetic data generation with ground-truth explanations, enabling reliable GNN explainability benchmarking.

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Area of Science:

  • Artificial Intelligence
  • Machine Learning
  • Graph Neural Networks

Background:

  • Evaluating graph neural network (GNN) explanations is critical for understanding their behavior.
  • Current graph datasets lack reliable ground-truth explanations, hindering quality assessment.

Purpose of the Study:

  • To introduce SHAPEGGEN, a synthetic graph data generator for creating benchmark datasets with ground-truth explanations.
  • To develop GRAPHXAI, a comprehensive library for benchmarking GNN explainability methods.

Main Methods:

  • SHAPEGGEN generates diverse synthetic graph datasets (varying sizes, degree distributions, homophily/heterophily).
  • Datasets include ground-truth explanations to facilitate evaluation.
  • The GRAPHXAI library integrates SHAPEGGEN, real-world datasets, GNN models, and evaluation tools.

Main Results:

  • SHAPEGGEN provides flexible synthetic data generation mimicking real-world scenarios.
  • GRAPHXAI offers a unified platform for benchmarking GNN explainability techniques.
  • The availability of ground-truth explanations enables robust evaluation of explanation quality.

Conclusions:

  • SHAPEGGEN and GRAPHXAI address the challenge of evaluating GNN explanations by providing reliable ground-truth data.
  • This facilitates the development and assessment of more accurate and trustworthy GNN explainability methods.