English

Multi-Modal Decentralized Reinforcement Learning for Modular Reconfigurable Lunar Robots

Robotics 2025-10-24 v1 Multiagent Systems

Abstract

Modular reconfigurable robots suit task-specific space operations, but the combinatorial growth of morphologies hinders unified control. We propose a decentralized reinforcement learning (Dec-RL) scheme where each module learns its own policy: wheel modules use Soft Actor-Critic (SAC) for locomotion and 7-DoF limbs use Proximal Policy Optimization (PPO) for steering and manipulation, enabling zero-shot generalization to unseen configurations. In simulation, the steering policy achieved a mean absolute error of 3.63{\deg} between desired and induced angles; the manipulation policy plateaued at 84.6 % success on a target-offset criterion; and the wheel policy cut average motor torque by 95.4 % relative to baseline while maintaining 99.6 % success. Lunar-analogue field tests validated zero-shot integration for autonomous locomotion, steering, and preliminary alignment for reconfiguration. The system transitioned smoothly among synchronous, parallel, and sequential modes for Policy Execution, without idle states or control conflicts, indicating a scalable, reusable, and robust approach for modular lunar robots.

Keywords

Cite

@article{arxiv.2510.20347,
  title  = {Multi-Modal Decentralized Reinforcement Learning for Modular Reconfigurable Lunar Robots},
  author = {Ashutosh Mishra and Shreya Santra and Elian Neppel and Edoardo M. Rossi Lombardi and Shamistan Karimov and Kentaro Uno and Kazuya Yoshida},
  journal= {arXiv preprint arXiv:2510.20347},
  year   = {2025}
}

Comments

Accepted in IEEE iSpaRo 2025. Awaiting Publication

R2 v1 2026-07-01T07:01:41.056Z