English

Decomposability and Parallel Computation of Multi-Agent LQR

Systems and Control 2021-03-09 v2 Artificial Intelligence Systems and Control Optimization and Control

Abstract

Individual agents in a multi-agent system (MAS) may have decoupled open-loop dynamics, but a cooperative control objective usually results in coupled closed-loop dynamics thereby making the control design computationally expensive. The computation time becomes even higher when a learning strategy such as reinforcement learning (RL) needs to be applied to deal with the situation when the agents dynamics are not known. To resolve this problem, we propose a parallel RL scheme for a linear quadratic regulator (LQR) design in a continuous-time linear MAS. The idea is to exploit the structural properties of two graphs embedded in the QQ and RR weighting matrices in the LQR objective to define an orthogonal transformation that can convert the original LQR design to multiple decoupled smaller-sized LQR designs. We show that if the MAS is homogeneous then this decomposition retains closed-loop optimality. Conditions for decomposability, an algorithm for constructing the transformation matrix, a parallel RL algorithm, and robustness analysis when the design is applied to non-homogeneous MAS are presented. Simulations show that the proposed approach can guarantee significant speed-up in learning without any loss in the cumulative value of the LQR cost.

Keywords

Cite

@article{arxiv.2010.08615,
  title  = {Decomposability and Parallel Computation of Multi-Agent LQR},
  author = {Gangshan Jing and He Bai and Jemin George and Aranya Chakrabortty},
  journal= {arXiv preprint arXiv:2010.08615},
  year   = {2021}
}

Comments

This paper contains proofs of all the theorems in the conference paper "Decomposability and Parallel Computation of Multi-Agent LQR"

R2 v1 2026-06-23T19:24:49.694Z