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Opt2Skill: Imitating Dynamically-Feasible Whole-Body Trajectories for Versatile Humanoid Loco-Manipulation

Fukang Liu, Zhaoyuan Gu, Yilin Cai, Ziyi Zhou, Hyunyoung Jung, Jaehwi Jang, Shijie Zhao, Sehoon Ha, Yue Chen, Danfei Xu, Ye Zhao

2025IEEE Robotics and Automation Letters9 citationsDOI

Abstract

Humanoid robots are designed to perform diverse loco-manipulation tasks. However, they face challenges due to their high-dimensional and unstable dynamics, as well as the complex contact-rich nature of the tasks. Model-based optimal control methods offer flexibility to define precise motion but are limited by high computational complexity and accurate contact sensing. On the other hand, reinforcement learning (RL) handles high-dimensional spaces with strong robustness but suffers from inefficient learning, unnatural motion, and sim-to-real gaps. To address these challenges, we introduce Opt2Skill, an end-to-end pipeline that combines model-based trajectory optimization with RL to achieve robust whole-body loco-manipulation. Opt2Skill generates dynamic feasible and contact-consistent reference motions for the Digit humanoid robot using differential dynamic programming (DDP) and trains RL policies to track these optimal trajectories. Our results demonstrate that Opt2Skill outperforms baselines that rely on human demonstrations and inverse kinematics-based references, both in motion tracking and task success rates. Furthermore, we show that incorporating trajectories with torque information improves contact force tracking in contact-involved tasks, such as wiping a table. We have successfully transferred our approach to real-world applications. <uri xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink">https://opt2skill.github.io</uri>

Topics & Concepts

Humanoid robotComputer scienceRobustness (evolution)Artificial intelligenceInverse dynamicsRobotTrajectoryFlexibility (engineering)Reinforcement learningTorqueiCubMotion controlTask (project management)Motion (physics)RoboticsComputer visionDifferential dynamic programmingControl engineeringDynamic programmingObserver (physics)Differential (mechanical device)Optimal controlRobot controlTrajectory optimizationContact forceTracking (education)Control theory (sociology)Merge (version control)SimulationPiecewiseTrainRobust controlRobot kinematicsProgramming by demonstrationRobotic Locomotion and ControlProsthetics and Rehabilitation RoboticsRobot Manipulation and Learning
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