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Main Authors: Zhao, Mengnan, Zhang, Lihe, Wang, Bo, Zheng, Tianhang, Zhong, Hong, Min, Geyong
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.24332
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author Zhao, Mengnan
Zhang, Lihe
Wang, Bo
Zheng, Tianhang
Zhong, Hong
Min, Geyong
author_facet Zhao, Mengnan
Zhang, Lihe
Wang, Bo
Zheng, Tianhang
Zhong, Hong
Min, Geyong
contents Fast Adversarial Training (FAT) has proven effective in enhancing model robustness by encouraging networks to learn perturbation-invariant representations. However, FAT often suffers from catastrophic overfitting (CO), where the model overfits to the training attack and fails to generalize to unseen ones. Moreover, robustness oriented optimization typically leads to notable performance degradation on clean inputs, and such degradation becomes increasingly severe as the perturbation budget grows. In this work, we conduct a comprehensive analysis of how guidance strength affects model performance by modulating perturbation and supervision levels across distinct confidence groups. The findings reveal that low confidence samples are the primary contributors to CO and the robustness accuracy trade off. Building on this insight, we propose a Distribution-aware Dynamic Guidance (DDG) strategy that dynamically adjusts both the perturbation budget and supervision signal. Specifically, DDG scales the perturbation magnitude according to the sample confidence at the ground truth class, thereby guiding samples toward consistent decision boundaries while mitigating the influence of learning spurious correlations. Simultaneously, it dynamically adjusts the supervision signal based on the prediction state of each sample, preventing overemphasis on incorrect signals. To alleviate potential gradient instability arising from dynamic guidance, we further design a weighted regularization constraint. Extensive experiments on standard benchmarks demonstrate that DDG effectively alleviates both CO and the robustness accuracy trade off.
format Preprint
id arxiv_https___arxiv_org_abs_2604_24332
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Mitigating Error Amplification in Fast Adversarial Training
Zhao, Mengnan
Zhang, Lihe
Wang, Bo
Zheng, Tianhang
Zhong, Hong
Min, Geyong
Machine Learning
Cryptography and Security
Fast Adversarial Training (FAT) has proven effective in enhancing model robustness by encouraging networks to learn perturbation-invariant representations. However, FAT often suffers from catastrophic overfitting (CO), where the model overfits to the training attack and fails to generalize to unseen ones. Moreover, robustness oriented optimization typically leads to notable performance degradation on clean inputs, and such degradation becomes increasingly severe as the perturbation budget grows. In this work, we conduct a comprehensive analysis of how guidance strength affects model performance by modulating perturbation and supervision levels across distinct confidence groups. The findings reveal that low confidence samples are the primary contributors to CO and the robustness accuracy trade off. Building on this insight, we propose a Distribution-aware Dynamic Guidance (DDG) strategy that dynamically adjusts both the perturbation budget and supervision signal. Specifically, DDG scales the perturbation magnitude according to the sample confidence at the ground truth class, thereby guiding samples toward consistent decision boundaries while mitigating the influence of learning spurious correlations. Simultaneously, it dynamically adjusts the supervision signal based on the prediction state of each sample, preventing overemphasis on incorrect signals. To alleviate potential gradient instability arising from dynamic guidance, we further design a weighted regularization constraint. Extensive experiments on standard benchmarks demonstrate that DDG effectively alleviates both CO and the robustness accuracy trade off.
title Mitigating Error Amplification in Fast Adversarial Training
topic Machine Learning
Cryptography and Security
url https://arxiv.org/abs/2604.24332