Legitimate Adversarial Patches
Jia Tan, Nan Ji, Haidong Xie, Xueshuang Xiang
Abstract
It is known that deep neural models are vulnerable to adversarial attacks. Digital attacks can craft imperceptible perturbations but lack of the ability to apply in physical environment. To address this issue, efforts have been investigated to study physical patch attacks in the physical world, especially for object detection models. Previous works mostly focus on evading the detection model itself but ignore the impact of human observers. In this paper, we study legitimate adversarial attacks that evade both human eyes and detection models in the physical world. To this end, we delve into the issue of patch rationality, and propose some indicators for evaluating the rationality of physical adversarial patches. Besides, we propose a novel framework with a two-stage training strategy to generate our legitimate adversarial patches (LAPs). Both in numerical simulations and physical experiments our LAPs have significant attack effects and visual rationality.