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Main Authors: Zhang, Chi, Li, Mingrui, Tong, Wenzhe, Huang, Xiaonan
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2510.26067
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author Zhang, Chi
Li, Mingrui
Tong, Wenzhe
Huang, Xiaonan
author_facet Zhang, Chi
Li, Mingrui
Tong, Wenzhe
Huang, Xiaonan
contents Tensegrity robots combine rigid rods and elastic cables, offering high resilience and deployability but at the same time posing major challenges for locomotion control due to their underactuated and highly coupled dynamics. This paper introduces a morphology-aware reinforcement learning framework that integrates a graph neural network (GNN) into the Soft Actor-Critic (SAC) algorithm. By representing the robot's physical topology as a graph, the proposed GNN-based policy captures coupling among components, enabling faster and more stable learning than conventional multilayer perceptron (MLP) policies. The method is validated on a physical 3-bar tensegrity robot across three locomotion primitives, including straight-line tracking and bidirectional turning. It shows superior sample efficiency, robustness to noise and stiffness variations, and improved trajectory accuracy. Additionally, the learned policies transfer directly from simulation to hardware without fine-tuning, achieving stable real-world locomotion. These results demonstrate the advantages of incorporating structural priors into reinforcement learning for tensegrity robot control.
format Preprint
id arxiv_https___arxiv_org_abs_2510_26067
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Morphology-Aware Graph Reinforcement Learning for Tensegrity Robot Locomotion
Zhang, Chi
Li, Mingrui
Tong, Wenzhe
Huang, Xiaonan
Robotics
Tensegrity robots combine rigid rods and elastic cables, offering high resilience and deployability but at the same time posing major challenges for locomotion control due to their underactuated and highly coupled dynamics. This paper introduces a morphology-aware reinforcement learning framework that integrates a graph neural network (GNN) into the Soft Actor-Critic (SAC) algorithm. By representing the robot's physical topology as a graph, the proposed GNN-based policy captures coupling among components, enabling faster and more stable learning than conventional multilayer perceptron (MLP) policies. The method is validated on a physical 3-bar tensegrity robot across three locomotion primitives, including straight-line tracking and bidirectional turning. It shows superior sample efficiency, robustness to noise and stiffness variations, and improved trajectory accuracy. Additionally, the learned policies transfer directly from simulation to hardware without fine-tuning, achieving stable real-world locomotion. These results demonstrate the advantages of incorporating structural priors into reinforcement learning for tensegrity robot control.
title Morphology-Aware Graph Reinforcement Learning for Tensegrity Robot Locomotion
topic Robotics
url https://arxiv.org/abs/2510.26067