Saved in:
Bibliographic Details
Main Authors: Zhao, Shiji, Xiong, Shukun, Yuan, Maoxun, Huang, Yao, Duan, Ranjie, Guo, Qing, Chen, Jiansheng, Duan, Haibin, Wei, Xingxing
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.25170
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910075212267520
author Zhao, Shiji
Xiong, Shukun
Yuan, Maoxun
Huang, Yao
Duan, Ranjie
Guo, Qing
Chen, Jiansheng
Duan, Haibin
Wei, Xingxing
author_facet Zhao, Shiji
Xiong, Shukun
Yuan, Maoxun
Huang, Yao
Duan, Ranjie
Guo, Qing
Chen, Jiansheng
Duan, Haibin
Wei, Xingxing
contents In complex environments, infrared object detection exhibits broad applicability and stability across diverse scenarios. However, infrared object detection is vulnerable to both common corruptions and adversarial examples, leading to potential security risks. To improve the robustness of infrared object detection, current methods mostly adopt a data-driven ideology, which only superficially drives the network to fit the training data without specifically considering the unique characteristics of infrared images, resulting in limited robustness. In this paper, we revisit infrared physical knowledge and find that relative thermal radiation relations between different classes can be regarded as a reliable knowledge source under the complex scenarios of adversarial examples and common corruptions. Thus, we theoretically model thermal radiation relations based on the rank order of gray values for different classes, and further quantify the stability of various inter-class thermal radiation relations. Based on the above theoretical framework, we propose Knowledge-Guided Adversarial Training (KGAT) for infrared object detection, in which infrared physical knowledge is embedded into the adversarial training process, and the predicted results are optimized to be consistent with the actual physical laws. Extensive experiments on three infrared datasets and six mainstream infrared object detection models demonstrate that KGAT effectively enhances both clean accuracy and robustness against adversarial attacks and common corruptions.
format Preprint
id arxiv_https___arxiv_org_abs_2603_25170
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Knowledge-Guided Adversarial Training for Infrared Object Detection via Thermal Radiation Modeling
Zhao, Shiji
Xiong, Shukun
Yuan, Maoxun
Huang, Yao
Duan, Ranjie
Guo, Qing
Chen, Jiansheng
Duan, Haibin
Wei, Xingxing
Computer Vision and Pattern Recognition
Artificial Intelligence
In complex environments, infrared object detection exhibits broad applicability and stability across diverse scenarios. However, infrared object detection is vulnerable to both common corruptions and adversarial examples, leading to potential security risks. To improve the robustness of infrared object detection, current methods mostly adopt a data-driven ideology, which only superficially drives the network to fit the training data without specifically considering the unique characteristics of infrared images, resulting in limited robustness. In this paper, we revisit infrared physical knowledge and find that relative thermal radiation relations between different classes can be regarded as a reliable knowledge source under the complex scenarios of adversarial examples and common corruptions. Thus, we theoretically model thermal radiation relations based on the rank order of gray values for different classes, and further quantify the stability of various inter-class thermal radiation relations. Based on the above theoretical framework, we propose Knowledge-Guided Adversarial Training (KGAT) for infrared object detection, in which infrared physical knowledge is embedded into the adversarial training process, and the predicted results are optimized to be consistent with the actual physical laws. Extensive experiments on three infrared datasets and six mainstream infrared object detection models demonstrate that KGAT effectively enhances both clean accuracy and robustness against adversarial attacks and common corruptions.
title Knowledge-Guided Adversarial Training for Infrared Object Detection via Thermal Radiation Modeling
topic Computer Vision and Pattern Recognition
Artificial Intelligence
url https://arxiv.org/abs/2603.25170