English

Co-Optimizing Reconfigurable Environments and Policies for Decentralized Multi-Agent Navigation

Robotics 2025-07-03 v2 Machine Learning Multiagent Systems

Abstract

This work views the multi-agent system and its surrounding environment as a co-evolving system, where the behavior of one affects the other. The goal is to take both agent actions and environment configurations as decision variables, and optimize these two components in a coordinated manner to improve some measure of interest. Towards this end, we consider the problem of decentralized multi-agent navigation in a cluttered environment, where we assume that the layout of the environment is reconfigurable. By introducing two sub-objectives -- multi-agent navigation and environment optimization -- we propose an agent-environment co-optimization problem and develop a coordinated algorithm that alternates between these sub-objectives to search for an optimal synthesis of agent actions and environment configurations; ultimately, improving the navigation performance. Due to the challenge of explicitly modeling the relation between the agents, the environment and their performance therein, we leverage policy gradient to formulate a model-free learning mechanism within the coordinated framework. A formal convergence analysis shows that our coordinated algorithm tracks the local minimum solution of an associated time-varying non-convex optimization problem. Experiments corroborate theoretical findings and show the benefits of co-optimization. Interestingly, the results also indicate that optimized environments can offer structural guidance to de-conflict agents in motion.

Keywords

Cite

@article{arxiv.2403.14583,
  title  = {Co-Optimizing Reconfigurable Environments and Policies for Decentralized Multi-Agent Navigation},
  author = {Zhan Gao and Guang Yang and Amanda Prorok},
  journal= {arXiv preprint arXiv:2403.14583},
  year   = {2025}
}
R2 v1 2026-06-28T15:28:54.487Z