RoboStressBench:面向具身场景物理视觉压力的VLM鲁棒性基准测试
阅读原文· arxiv.orgRoboStressBench是一个用于评估视觉语言模型在具身场景中对物理视觉压力鲁棒性的基准测试。它从逆向图形学角度出发,将视觉压力系统性地分解为材质、视角、光照和几何四个基于物理的维度。该研究通过对先进模型的全面评估,揭示了特定压力下的失败模式,并发现不同物理因素对识别、推理和规划等能力的影响存在差异。此外,研究还引入了一种压力感知智能体求解器,它能在推理前检测视觉压力源并调用视觉编辑技能,以提升模型在复杂场景中的鲁棒性。
Vision-Language Models (VLMs) have shown strong visual understanding and are increasingly deployed in embodied AI systems, where reliable perception under real conditions is essential. However, existing benchmarks assess VLMs using clean images or isolated perturbations rather than stresses caused by physical scene formation. This design has two limitations: it covers only a narrow subset of everyday visual stresses, and some perturbations rarely appear in realistic embodied scenes. This gap raises a fundamental question: how can we define visual stress in a principled way that captures the diverse factors encountered in physical environments? To address this question, we formulate visual perception from an inverse graphics perspective and introduce RoboStressBench, a benchmark for evaluating VLM robustness to physical visual stress in embodied scenes. Inspired by the physical rendering equation, RoboStressBench decomposes visual stress into four physically grounded dimensions: Material (M), Viewpoint (V), Lighting (L), and Geometry (G). This design enables RoboStressBench to cover a broad range of visual stresses in real-world environments, while allowing controlled analysis of their effects on VLM capabilities such as visual recognition, reasoning, and planning. Through comprehensive evaluations of state-of-the-art VLMs, we identify stress-specific failure modes and reveal that different physical factors degrade different embodied capabilities, which are often obscured by aggregate accuracy. We further introduce a stress-aware agentic solver that detects visual stressors and invokes visual-editing skills before reasoning, improving robustness in high-stress scenarios. Overall, RoboStressBench provides a principled evaluation framework for diagnosing and improving VLM perception under real-world physical stress, supporting the development of more reliable embodied AI systems.