English

Scalable Task-Driven Robotic Swarm Control via Collision Avoidance and Learning Mean-Field Control

Robotics 2023-02-10 v3 Artificial Intelligence Machine Learning

Abstract

In recent years, reinforcement learning and its multi-agent analogue have achieved great success in solving various complex control problems. However, multi-agent reinforcement learning remains challenging both in its theoretical analysis and empirical design of algorithms, especially for large swarms of embodied robotic agents where a definitive toolchain remains part of active research. We use emerging state-of-the-art mean-field control techniques in order to convert many-agent swarm control into more classical single-agent control of distributions. This allows profiting from advances in single-agent reinforcement learning at the cost of assuming weak interaction between agents. However, the mean-field model is violated by the nature of real systems with embodied, physically colliding agents. Thus, we combine collision avoidance and learning of mean-field control into a unified framework for tractably designing intelligent robotic swarm behavior. On the theoretical side, we provide novel approximation guarantees for general mean-field control both in continuous spaces and with collision avoidance. On the practical side, we show that our approach outperforms multi-agent reinforcement learning and allows for decentralized open-loop application while avoiding collisions, both in simulation and real UAV swarms. Overall, we propose a framework for the design of swarm behavior that is both mathematically well-founded and practically useful, enabling the solution of otherwise intractable swarm problems.

Keywords

Cite

@article{arxiv.2209.07420,
  title  = {Scalable Task-Driven Robotic Swarm Control via Collision Avoidance and Learning Mean-Field Control},
  author = {Kai Cui and Mengguang Li and Christian Fabian and Heinz Koeppl},
  journal= {arXiv preprint arXiv:2209.07420},
  year   = {2023}
}

Comments

Accepted to the 40th IEEE Conference on Robotics and Automation (ICRA)

R2 v1 2026-06-28T01:22:46.131Z