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Main Authors: Liu, Ziyang, Wang, Hongyuan, Wang, Zijian, Lu, Yinxi, Zang, Yunzhao, Yan, Zhiqiang, Ning, Qianhao
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2605.17772
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author Liu, Ziyang
Wang, Hongyuan
Wang, Zijian
Lu, Yinxi
Zang, Yunzhao
Yan, Zhiqiang
Ning, Qianhao
author_facet Liu, Ziyang
Wang, Hongyuan
Wang, Zijian
Lu, Yinxi
Zang, Yunzhao
Yan, Zhiqiang
Ning, Qianhao
contents Physical adversarial attacks often overfit single surrogate models and optimization objectives. While ensemble attacks can mitigate this, existing methods struggle with severe gradient conflicts within restricted physical texture spaces, significantly degrading cross-model transferability. To bridge this gap, this paper proposes a Joint Multi-Objective and Multi-Model Optimization Framework (JMOF) that leverages quantitative similarity analysis to select the optimal surrogate model ensemble. Within JMOF, a dual-level mechanism jointly suppresses prediction outputs and flattens intermediate feature distributions, balancing attack efficiency with deep generalization. Additionally, an Orthogonal Gradient Alignment (OGA) strategy resolves cross-model gradient conflicts, transforming mutually repulsive gradients into synergistic optimization directions. Extensive simulated and real-world experiments demonstrate that JMOF outperforms state-of-the-art baselines against diverse black-box detectors. Crucially, JMOF exhibits substantial cross-vision-task generalization, generating attacks capable of simultaneously deceiving object detection and semantic segmentation or monocular depth estimation models. This research advances the generalization limits of physical adversarial attacks, providing a robust framework for evaluating visual AI vulnerabilities in real-world deployments.
format Preprint
id arxiv_https___arxiv_org_abs_2605_17772
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Towards Universal Physical Adversarial Attacks via a Joint Multi-Objective and Multi-Model Optimization Framework
Liu, Ziyang
Wang, Hongyuan
Wang, Zijian
Lu, Yinxi
Zang, Yunzhao
Yan, Zhiqiang
Ning, Qianhao
Computer Vision and Pattern Recognition
Physical adversarial attacks often overfit single surrogate models and optimization objectives. While ensemble attacks can mitigate this, existing methods struggle with severe gradient conflicts within restricted physical texture spaces, significantly degrading cross-model transferability. To bridge this gap, this paper proposes a Joint Multi-Objective and Multi-Model Optimization Framework (JMOF) that leverages quantitative similarity analysis to select the optimal surrogate model ensemble. Within JMOF, a dual-level mechanism jointly suppresses prediction outputs and flattens intermediate feature distributions, balancing attack efficiency with deep generalization. Additionally, an Orthogonal Gradient Alignment (OGA) strategy resolves cross-model gradient conflicts, transforming mutually repulsive gradients into synergistic optimization directions. Extensive simulated and real-world experiments demonstrate that JMOF outperforms state-of-the-art baselines against diverse black-box detectors. Crucially, JMOF exhibits substantial cross-vision-task generalization, generating attacks capable of simultaneously deceiving object detection and semantic segmentation or monocular depth estimation models. This research advances the generalization limits of physical adversarial attacks, providing a robust framework for evaluating visual AI vulnerabilities in real-world deployments.
title Towards Universal Physical Adversarial Attacks via a Joint Multi-Objective and Multi-Model Optimization Framework
topic Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2605.17772