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Main Authors: Wei, Sizhe, Chen, Xulin, Xie, Fengze, Katz, Garrett Ethan, Gan, Zhenyu, Gan, Lu
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.00727
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author Wei, Sizhe
Chen, Xulin
Xie, Fengze
Katz, Garrett Ethan
Gan, Zhenyu
Gan, Lu
author_facet Wei, Sizhe
Chen, Xulin
Xie, Fengze
Katz, Garrett Ethan
Gan, Zhenyu
Gan, Lu
contents Reinforcement learning has recently enabled impressive locomotion capabilities on legged robots; however, most policy architectures remain morphology- and symmetry-agnostic, leading to inefficient training and limited generalization. This work introduces MS-PPO, a morphological-symmetry-equivariant policy learning framework that encodes robot kinematic structure and morphological symmetries directly into the policy network. We construct a morphology-informed graph neural architecture that is provably equivariant with respect to the robot's morphological symmetry group actions, ensuring consistent policy responses under symmetric states while maintaining invariance in value estimation. This design eliminates the need for tedious reward shaping or costly data augmentation, which are typically required to enforce symmetry. We evaluate MS-PPO in simulation on Unitree Go2 and Xiaomi CyberDog2 robots across diverse locomotion tasks, including trotting, pronking, slope walking, and bipedal turning, and further deploy the learned policies on hardware. Extensive experiments show that MS-PPO achieves superior training stability, symmetry generalization ability, and sample efficiency in challenging locomotion tasks, compared to state-of-the-art baselines. These findings demonstrate that embedding both kinematic structure and morphological symmetry into policy learning provides a powerful inductive bias for legged robot locomotion control. Our code will be made publicly available at https://lunarlab-gatech.github.io/MS-PPO/.
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publishDate 2025
record_format arxiv
spellingShingle MS-PPO: Morphological-Symmetry-Equivariant Policy for Legged Robot Locomotion
Wei, Sizhe
Chen, Xulin
Xie, Fengze
Katz, Garrett Ethan
Gan, Zhenyu
Gan, Lu
Robotics
Reinforcement learning has recently enabled impressive locomotion capabilities on legged robots; however, most policy architectures remain morphology- and symmetry-agnostic, leading to inefficient training and limited generalization. This work introduces MS-PPO, a morphological-symmetry-equivariant policy learning framework that encodes robot kinematic structure and morphological symmetries directly into the policy network. We construct a morphology-informed graph neural architecture that is provably equivariant with respect to the robot's morphological symmetry group actions, ensuring consistent policy responses under symmetric states while maintaining invariance in value estimation. This design eliminates the need for tedious reward shaping or costly data augmentation, which are typically required to enforce symmetry. We evaluate MS-PPO in simulation on Unitree Go2 and Xiaomi CyberDog2 robots across diverse locomotion tasks, including trotting, pronking, slope walking, and bipedal turning, and further deploy the learned policies on hardware. Extensive experiments show that MS-PPO achieves superior training stability, symmetry generalization ability, and sample efficiency in challenging locomotion tasks, compared to state-of-the-art baselines. These findings demonstrate that embedding both kinematic structure and morphological symmetry into policy learning provides a powerful inductive bias for legged robot locomotion control. Our code will be made publicly available at https://lunarlab-gatech.github.io/MS-PPO/.
title MS-PPO: Morphological-Symmetry-Equivariant Policy for Legged Robot Locomotion
topic Robotics
url https://arxiv.org/abs/2512.00727