DepthVanish: Optimizing Adversarial Interval Structures for Stereo-Depth-Invisible Patches

Abstract: Stereo Depth estimation is a critical task in autonomous driving and robotics, where inaccuracies (such as misidentifying nearby objects as distant) can lead to dangerous situations. Adversarial attacks against stereo depth estimation can help reveal vulnerabilities before deployment. Previous work has shown that repeating optimized textures can effectively mislead stereo depth estimation in digital settings. However, our research reveals that these naively repeated texture structures perform poorly in physical-world implementations, i.e., when deployed as patches, limiting their practical utility for testing stereo depth estimation systems. In this work, for the first time, we discover that introducing regular intervals between repeated textures, creating a striped structure, significantly enhances the patch attack effectiveness. Through extensive experimentation, we analyze how variations of this novel structure influence the performance. Based on these insights, we develop a novel stereo depth attack that jointly optimizes both the striped structure and texture elements. Our generated adversarial patches can be inserted into any scenes and successfully attack state-of-the-art stereo depth estimation methods, i.e., RAFT-Stereo and STTR. Most critically, our patch can also attack commercial RGB-D cameras (Intel RealSense) in real-world conditions, demonstrating their practical relevance for security assessment of stereo systems.