Stabilizing Humanoid Robot Trajectory Generation via Physics-Informed Learning and Control-Informed Steering
Abstract
Recent trends in humanoid robot control have successfully employed imitation learning to enable the learned generation of smooth, human-like trajectories from human data. While these approaches make more realistic motions possible, they are limited by the amount of available motion data, and do not incorporate prior knowledge about the physical laws governing the system and its interactions with the environment. Thus they may violate such laws, leading to divergent trajectories and sliding contacts which limit real-world stability. We address such limitations via a two-pronged learning strategy which leverages the known physics of the system and fundamental control principles. First, we encode physics priors during supervised imitation learning to promote trajectory feasibility. Second, we minimize drift at inference time by applying a proportional-integral controller directly to the generated output state. We validate our method on various locomotion behaviors for the ergoCub humanoid robot, where a physics-informed loss encourages zero contact foot velocity. Our experiments demonstrate that the proposed approach is compatible with multiple controllers on a real robot and significantly improves the accuracy and physical constraint conformity of generated trajectories.
Keywords
Cite
@article{arxiv.2509.24697,
title = {Stabilizing Humanoid Robot Trajectory Generation via Physics-Informed Learning and Control-Informed Steering},
author = {Evelyn D'Elia and Paolo Maria Viceconte and Lorenzo Rapetti and Diego Ferigo and Giulio Romualdi and Giuseppe L'Erario and Raffaello Camoriano and Daniele Pucci},
journal= {arXiv preprint arXiv:2509.24697},
year = {2025}
}
Comments
This paper has been accepted for publication at the IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Hangzhou, China, 2025