Title: Distributed Feedback Optimization of Linear Multi-agent Systems

Abstract: Feedback optimization is an increasingly popular control paradigm to optimize dynamical systems, accounting for control objectives that concern the system's operation at steady-state. Existing feedback optimization techniques heavily rely on centralized system and controller architectures, and thus suffer from scalability and privacy issues when systems become large-scale. In this paper, we propose and study a distributed architecture for feedback optimization, in which each agent updates its local control state by combining the average of its neighbors with a local negative-gradient step. Under convexity and smoothness assumptions, we establish convergence of the control method to a fixed point. By reinforcing the assumptions to restricted strong convexity of the cost, we show that our algorithm converges linearly to a neighborhood of the optimal point, where the size of the neighborhood depends on the choice of the stepsize. Simulations corroborate the theoretical results.