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Main Authors: Wang, Xuan, Liang, Siyuan, Liao, Dongping, Fang, Han, Liu, Aishan, Cao, Xiaochun, Lu, Yu-liang, Chang, Ee-Chien, Gao, Xitong
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.16872
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author Wang, Xuan
Liang, Siyuan
Liao, Dongping
Fang, Han
Liu, Aishan
Cao, Xiaochun
Lu, Yu-liang
Chang, Ee-Chien
Gao, Xitong
author_facet Wang, Xuan
Liang, Siyuan
Liao, Dongping
Fang, Han
Liu, Aishan
Cao, Xiaochun
Lu, Yu-liang
Chang, Ee-Chien
Gao, Xitong
contents Institutions with limited data and computing resources often outsource model training to third-party providers in a semi-honest setting, assuming adherence to prescribed training protocols with pre-defined learning paradigm (e.g., supervised or semi-supervised learning). However, this practice can introduce severe security risks, as adversaries may poison the training data to embed backdoors into the resulting model. Existing detection approaches predominantly rely on statistical analyses, which often fail to maintain universally accurate detection accuracy across different learning paradigms. To address this challenge, we propose a unified backdoor detection framework in the semi-honest setting that exploits cross-examination of model inconsistencies between two independent service providers. Specifically, we integrate central kernel alignment to enable robust feature similarity measurements across different model architectures and learning paradigms, thereby facilitating precise recovery and identification of backdoor triggers. We further introduce backdoor fine-tuning sensitivity analysis to distinguish backdoor triggers from adversarial perturbations, substantially reducing false positives. Extensive experiments demonstrate that our method achieves superior detection performance, improving accuracy by 5.4%, 1.6%, and 11.9% over SoTA baselines across supervised, semi-supervised, and autoregressive learning tasks, respectively. Notably, it is the first to effectively detect backdoors in multimodal large language models, further highlighting its broad applicability and advancing secure deep learning.
format Preprint
id arxiv_https___arxiv_org_abs_2503_16872
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publishDate 2025
record_format arxiv
spellingShingle Lie Detector: Unified Backdoor Detection via Cross-Examination Framework
Wang, Xuan
Liang, Siyuan
Liao, Dongping
Fang, Han
Liu, Aishan
Cao, Xiaochun
Lu, Yu-liang
Chang, Ee-Chien
Gao, Xitong
Machine Learning
Computer Vision and Pattern Recognition
Institutions with limited data and computing resources often outsource model training to third-party providers in a semi-honest setting, assuming adherence to prescribed training protocols with pre-defined learning paradigm (e.g., supervised or semi-supervised learning). However, this practice can introduce severe security risks, as adversaries may poison the training data to embed backdoors into the resulting model. Existing detection approaches predominantly rely on statistical analyses, which often fail to maintain universally accurate detection accuracy across different learning paradigms. To address this challenge, we propose a unified backdoor detection framework in the semi-honest setting that exploits cross-examination of model inconsistencies between two independent service providers. Specifically, we integrate central kernel alignment to enable robust feature similarity measurements across different model architectures and learning paradigms, thereby facilitating precise recovery and identification of backdoor triggers. We further introduce backdoor fine-tuning sensitivity analysis to distinguish backdoor triggers from adversarial perturbations, substantially reducing false positives. Extensive experiments demonstrate that our method achieves superior detection performance, improving accuracy by 5.4%, 1.6%, and 11.9% over SoTA baselines across supervised, semi-supervised, and autoregressive learning tasks, respectively. Notably, it is the first to effectively detect backdoors in multimodal large language models, further highlighting its broad applicability and advancing secure deep learning.
title Lie Detector: Unified Backdoor Detection via Cross-Examination Framework
topic Machine Learning
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2503.16872