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Autori principali: Li, Xiaoyang, Tao, Linwei, Lu, Haohui, Dong, Minjing, Gao, Junbin, Xu, Chang
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2506.23782
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author Li, Xiaoyang
Tao, Linwei
Lu, Haohui
Dong, Minjing
Gao, Junbin
Xu, Chang
author_facet Li, Xiaoyang
Tao, Linwei
Lu, Haohui
Dong, Minjing
Gao, Junbin
Xu, Chang
contents Graph Neural Networks (GNNs) have demonstrated strong predictive performance on relational data; however, their confidence estimates often misalign with actual predictive correctness, posing significant limitations for deployment in safety-critical settings. While existing graph-aware calibration methods seek to mitigate this limitation, they primarily depend on coarse one-hop statistics, such as neighbor-predicted confidence, or latent node embeddings, thereby neglecting the fine-grained structural heterogeneity inherent in graph topology. In this work, we propose Wavelet-Aware Temperature Scaling (WATS), a post-hoc calibration framework that assigns node-specific temperatures based on tunable heat-kernel graph wavelet features. Specifically, WATS harnesses the scalability and topology sensitivity of graph wavelets to refine confidence estimates, all without necessitating model retraining or access to neighboring logits or predictions. Extensive evaluations across seven benchmark datasets with varying graph structures and two GNN backbones demonstrate that WATS achieves the lowest Expected Calibration Error (ECE) among all compared methods, outperforming both classical and graph-specific baselines by up to 42.3\% in ECE and reducing calibration variance by 17.24\% on average compared with graph-specific methods. Moreover, WATS remains computationally efficient, scaling well across graphs of diverse sizes and densities. Code will be released based on publication.
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publishDate 2025
record_format arxiv
spellingShingle WATS: Calibrating Graph Neural Networks with Wavelet-Aware Temperature Scaling
Li, Xiaoyang
Tao, Linwei
Lu, Haohui
Dong, Minjing
Gao, Junbin
Xu, Chang
Machine Learning
Artificial Intelligence
Graph Neural Networks (GNNs) have demonstrated strong predictive performance on relational data; however, their confidence estimates often misalign with actual predictive correctness, posing significant limitations for deployment in safety-critical settings. While existing graph-aware calibration methods seek to mitigate this limitation, they primarily depend on coarse one-hop statistics, such as neighbor-predicted confidence, or latent node embeddings, thereby neglecting the fine-grained structural heterogeneity inherent in graph topology. In this work, we propose Wavelet-Aware Temperature Scaling (WATS), a post-hoc calibration framework that assigns node-specific temperatures based on tunable heat-kernel graph wavelet features. Specifically, WATS harnesses the scalability and topology sensitivity of graph wavelets to refine confidence estimates, all without necessitating model retraining or access to neighboring logits or predictions. Extensive evaluations across seven benchmark datasets with varying graph structures and two GNN backbones demonstrate that WATS achieves the lowest Expected Calibration Error (ECE) among all compared methods, outperforming both classical and graph-specific baselines by up to 42.3\% in ECE and reducing calibration variance by 17.24\% on average compared with graph-specific methods. Moreover, WATS remains computationally efficient, scaling well across graphs of diverse sizes and densities. Code will be released based on publication.
title WATS: Calibrating Graph Neural Networks with Wavelet-Aware Temperature Scaling
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2506.23782