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Main Authors: Feng, Zhou, Chen, Jiahao, Zhou, Chunyi, Pu, Yuwen, Du, Tianyu, Li, Jinbao, Chen, Jianhai, Ji, Shouling
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.10402
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author Feng, Zhou
Chen, Jiahao
Zhou, Chunyi
Pu, Yuwen
Du, Tianyu
Li, Jinbao
Chen, Jianhai
Ji, Shouling
author_facet Feng, Zhou
Chen, Jiahao
Zhou, Chunyi
Pu, Yuwen
Du, Tianyu
Li, Jinbao
Chen, Jianhai
Ji, Shouling
contents Deep neural networks (DNNs) underpin critical applications yet remain vulnerable to backdoor attacks, typically reliant on heuristic brute-force methods. Despite significant empirical advancements in backdoor research, the lack of rigorous theoretical analysis limits understanding of underlying mechanisms, constraining attack predictability and adaptability. Therefore, we provide a theoretical analysis targeting backdoor attacks, focusing on how sparse decision boundaries enable disproportionate model manipulation. Based on this finding, we derive a closed-form, ambiguous boundary region, wherein negligible relabeled samples induce substantial misclassification. Influence function analysis further quantifies significant parameter shifts caused by these margin samples, with minimal impact on clean accuracy, formally grounding why such low poison rates suffice for efficacious attacks. Leveraging these insights, we propose Eminence, an explainable and robust black-box backdoor framework with provable theoretical guarantees and inherent stealth properties. Eminence optimizes a universal, visually subtle trigger that strategically exploits vulnerable decision boundaries and effectively achieves robust misclassification with exceptionally low poison rates (< 0.1%, compared to SOTA methods typically requiring > 1%). Comprehensive experiments validate our theoretical discussions and demonstrate the effectiveness of Eminence, confirming an exponential relationship between margin poisoning and adversarial boundary manipulation. Eminence maintains > 90% attack success rate, exhibits negligible clean-accuracy loss, and demonstrates high transferability across diverse models, datasets and scenarios.
format Preprint
id arxiv_https___arxiv_org_abs_2512_10402
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle The Eminence in Shadow: Exploiting Feature Boundary Ambiguity for Robust Backdoor Attacks
Feng, Zhou
Chen, Jiahao
Zhou, Chunyi
Pu, Yuwen
Du, Tianyu
Li, Jinbao
Chen, Jianhai
Ji, Shouling
Machine Learning
Artificial Intelligence
Deep neural networks (DNNs) underpin critical applications yet remain vulnerable to backdoor attacks, typically reliant on heuristic brute-force methods. Despite significant empirical advancements in backdoor research, the lack of rigorous theoretical analysis limits understanding of underlying mechanisms, constraining attack predictability and adaptability. Therefore, we provide a theoretical analysis targeting backdoor attacks, focusing on how sparse decision boundaries enable disproportionate model manipulation. Based on this finding, we derive a closed-form, ambiguous boundary region, wherein negligible relabeled samples induce substantial misclassification. Influence function analysis further quantifies significant parameter shifts caused by these margin samples, with minimal impact on clean accuracy, formally grounding why such low poison rates suffice for efficacious attacks. Leveraging these insights, we propose Eminence, an explainable and robust black-box backdoor framework with provable theoretical guarantees and inherent stealth properties. Eminence optimizes a universal, visually subtle trigger that strategically exploits vulnerable decision boundaries and effectively achieves robust misclassification with exceptionally low poison rates (< 0.1%, compared to SOTA methods typically requiring > 1%). Comprehensive experiments validate our theoretical discussions and demonstrate the effectiveness of Eminence, confirming an exponential relationship between margin poisoning and adversarial boundary manipulation. Eminence maintains > 90% attack success rate, exhibits negligible clean-accuracy loss, and demonstrates high transferability across diverse models, datasets and scenarios.
title The Eminence in Shadow: Exploiting Feature Boundary Ambiguity for Robust Backdoor Attacks
topic Machine Learning
Artificial Intelligence
url https://arxiv.org/abs/2512.10402