Physical AI refers to AI systems designed to perceive, reason about, and act within the physical world, integrating sensing, computation, and actuation to interact with real environments. It encompasses robotics, autonomous vehicles, industrial automation, and embodied agents that must contend with physical constraints such as dynamics, uncertainty, and real-time requirements. Research areas include perception under sensor noise, physics-informed modeling, sim-to-real transfer, and safe autonomous operation in unstructured environments.

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PhyCo: Learning Controllable Physical Priors for Generative Motion

Modern video diffusion models excel at appearance synthesis but still struggle with physical consistency: objects drift, collisions lack realistic rebound, and material responses seldom match their underlying properties. We present PhyCo, a framework that introduces continuous, interpretable, and physically grounded control into video generation. Our approach integrates three key components: (i) a large-scale dataset of over 100K photorealistic simulation videos where friction, restitution, deformation, and force are systematically varied across diverse scenarios; (ii) physics-supervised fine-tuning of a pretrained diffusion model using a ControlNet conditioned on pixel-aligned physical property maps; and (iii) VLM-guided reward optimization, where a fine-tuned vision-language model evaluates generated videos with targeted physics queries and provides differentiable feedback. This combination enables a generative model to produce physically consistent and controllable outputs through variations in physical attributes-without any simulator or geometry reconstruction at inference. On the Physics-IQ benchmark, PhyCo significantly improves physical realism over strong baselines, and human studies confirm clearer and more faithful control over physical attributes. Our results demonstrate a scalable path toward physically consistent, controllable generative video models that generalize beyond synthetic training environments.