中文

A Closed-Loop Multi-Agent Framework for Robust Multi-Robot Manipulation

机器人学 2026-07-08 v1

摘要

Multi-robot systems provide the parallelism and redundancy necessary for long-horizon tasks, while Large Language Models (LLMs) offer the reasoning capabilities to decompose these objectives into actionable plans. However, effectively grounding this high-level reasoning in physical multi-robot execution remains an open challenge. Existing LLM-based approaches fall mainly into two categories: Single-robot methods achieve robust contact-rich manipulation but lack the coordination mechanisms required for tasks spanning multiple workspaces. Current multi-robot frameworks focus on high-level planning, often treating manipulation as an idealized primitive that fails to account for real-world execution uncertainties. To address this, we propose a hierarchical closed-loop agentic LLM-based framework to ensure robust multi-robot manipulation. Our system consists of three specialized agents: the Planning Agent decomposes instructions into allocated sub-tasks, the Manipulation Agent for each robot executes actions via adaptive tool use, and the Verification Agent closes the loop by monitoring physical outcomes and feeding back semantic corrections. Extensive real-world experiments demonstrate that our framework achieves superior success rates, ensures robust adaptability ranging from single to cross workspace manipulation, and offers a generalizable approach for diverse manipulation tasks.

引用

@article{arxiv.2607.06990,
  title  = {A Closed-Loop Multi-Agent Framework for Robust Multi-Robot Manipulation},
  author = {Yi-Xiang He and Lan Wei and Haoming Cen and Jian-Jian Jiang and Zhuohao Li and Guanxing Lu and Yihan Yang and Dandan Zhang and Wei-Shi Zheng},
  journal= {arXiv preprint arXiv:2607.06990},
  year   = {2026}
}

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