📝 SummarXiv

Abstract

This paper presents a new method for achieving dynamic consensus in linear discrete-time homogeneous multi-agent systems (MAS) with marginally stable or unstable dynamics. The guarantee of consensus in this setting involves a set of constraints based on the graph's spectral properties, complicating the design of the coupling gains. This challenge intensifies for large-scale systems with diverse graph Laplacian spectra. The proposed approach reformulates the dynamic consensus problem with a prescribed convergence rate using a state-action value function framework inspired by optimal control theory. Specifically, a synthetic linear quadratic regulation (LQR) formulation is introduced to encode the consensus objective, enabling its translation into a convex semidefinite programming (SDP) problem. The resulting SDP is applicable in both model-based and model-free settings for jointly designing the local feedback and coupling gains. To handle the inherent non-convex feasibility conditions, a convex-concave decomposition strategy is employed. Adaptation of the method in a completely model-free set-up eliminates the need for system identification or knowledge of the agents' dynamics. Instead, it relies on input-state data collection and offers an entirely data-driven equivalent SDP formulation. Finally, a new algorithm balancing feasibility, convergence rate, robustness, and energy efficiency, is established to provide design flexibility. Numerical simulations validate the method's effectiveness in various scenarios.