English

Efficient Reinforcement Learning using Linear Koopman Dynamics for Nonlinear Robotic Systems

Robotics 2026-04-23 v1 Systems and Control Systems and Control

Abstract

This paper presents a model-based reinforcement learning (RL) framework for optimal closed-loop control of nonlinear robotic systems. The proposed approach learns linear lifted dynamics through Koopman operator theory and integrates the resulting model into an actor-critic architecture for policy optimization, where the policy represents a parameterized closed-loop controller. To reduce computational cost and mitigate model rollout errors, policy gradients are estimated using one-step predictions of the learned dynamics rather than multi-step propagation. This leads to an online mini-batch policy gradient framework that enables policy improvement from streamed interaction data. The proposed framework is evaluated on several simulated nonlinear control benchmarks and two real-world hardware platforms, including a Kinova Gen3 robotic arm and a Unitree Go1 quadruped. Experimental results demonstrate improved sample efficiency over model-free RL baselines, superior control performance relative to model-based RL baselines, and control performance comparable to classical model-based methods that rely on exact system dynamics.

Keywords

Cite

@article{arxiv.2604.19980,
  title  = {Efficient Reinforcement Learning using Linear Koopman Dynamics for Nonlinear Robotic Systems},
  author = {Wenjian Hao and Yuxuan Fang and Zehui Lu and Shaoshuai Mou},
  journal= {arXiv preprint arXiv:2604.19980},
  year   = {2026}
}
R2 v1 2026-07-01T12:29:21.948Z