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Auteurs principaux: Liu, Yaohua, Gao, Jiaxin, Jiao, Xianghao, Liu, Zhu, Fan, Xin, Liu, Risheng
Format: Preprint
Publié: 2023
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Accès en ligne:https://arxiv.org/abs/2310.12713
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author Liu, Yaohua
Gao, Jiaxin
Jiao, Xianghao
Liu, Zhu
Fan, Xin
Liu, Risheng
author_facet Liu, Yaohua
Gao, Jiaxin
Jiao, Xianghao
Liu, Zhu
Fan, Xin
Liu, Risheng
contents Adversarial Training (AT), pivotal in fortifying the robustness of deep learning models, is extensively adopted in practical applications. However, prevailing AT methods, relying on direct iterative updates for target model's defense, frequently encounter obstacles such as unstable training and catastrophic overfitting. In this context, our work illuminates the potential of leveraging the target model's historical states as a proxy to provide effective initialization and defense prior, which results in a general proxy guided defense framework, `LAST' ({\bf L}earn from the P{\bf ast}). Specifically, LAST derives response of the proxy model as dynamically learned fast weights, which continuously corrects the update direction of the target model. Besides, we introduce a self-distillation regularized defense objective, ingeniously designed to steer the proxy model's update trajectory without resorting to external teacher models, thereby ameliorating the impact of catastrophic overfitting on performance. Extensive experiments and ablation studies showcase the framework's efficacy in markedly improving model robustness (e.g., up to 9.2\% and 20.3\% enhancement in robust accuracy on CIFAR10 and CIFAR100 datasets, respectively) and training stability. These improvements are consistently observed across various model architectures, larger datasets, perturbation sizes, and attack modalities, affirming LAST's ability to consistently refine both single-step and multi-step AT strategies. The code will be available at~\url{https://github.com/callous-youth/LAST}.
format Preprint
id arxiv_https___arxiv_org_abs_2310_12713
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Learn from the Past: A Proxy Guided Adversarial Defense Framework with Self Distillation Regularization
Liu, Yaohua
Gao, Jiaxin
Jiao, Xianghao
Liu, Zhu
Fan, Xin
Liu, Risheng
Machine Learning
Adversarial Training (AT), pivotal in fortifying the robustness of deep learning models, is extensively adopted in practical applications. However, prevailing AT methods, relying on direct iterative updates for target model's defense, frequently encounter obstacles such as unstable training and catastrophic overfitting. In this context, our work illuminates the potential of leveraging the target model's historical states as a proxy to provide effective initialization and defense prior, which results in a general proxy guided defense framework, `LAST' ({\bf L}earn from the P{\bf ast}). Specifically, LAST derives response of the proxy model as dynamically learned fast weights, which continuously corrects the update direction of the target model. Besides, we introduce a self-distillation regularized defense objective, ingeniously designed to steer the proxy model's update trajectory without resorting to external teacher models, thereby ameliorating the impact of catastrophic overfitting on performance. Extensive experiments and ablation studies showcase the framework's efficacy in markedly improving model robustness (e.g., up to 9.2\% and 20.3\% enhancement in robust accuracy on CIFAR10 and CIFAR100 datasets, respectively) and training stability. These improvements are consistently observed across various model architectures, larger datasets, perturbation sizes, and attack modalities, affirming LAST's ability to consistently refine both single-step and multi-step AT strategies. The code will be available at~\url{https://github.com/callous-youth/LAST}.
title Learn from the Past: A Proxy Guided Adversarial Defense Framework with Self Distillation Regularization
topic Machine Learning
url https://arxiv.org/abs/2310.12713