Optimal Sparse $H_\infty$ Controller Design for Networked Control Systems

This paper provides a comprehensive analysis of the design of optimal sparse $H_\infty$ controllers for continuous-time linear time-invariant systems. The sparsity of a controller has received increasing attention as it represents the communication and computation efficiency of feedback networks. However, the design of optimal sparse $H_\infty$ controllers remains an open and challenging problem due to its non-convexity, and we cannot design a first-order algorithm to analyze since we lack an analytical expression for a given controller. In this paper, we consider two typical problems. First, design a sparse $H_\infty$ controller subject to a specified threshold, which minimizes the sparsity of the controller while satisfying the given performance requirement. Second, design a sparsity-promoting $H_\infty$ controller, which strikes a balance between the system performance and the controller sparsity. For both problems, we propose a relaxed convex problem and we show that any feasible solution of the relaxed problem is feasible for the original problem. Subsequently, we design an iterative linear matrix inequality (ILMI) for both problems with guaranteed convergence. We further characterize the first-order optimality using the Karush-Kuhn-Tucker (KKT) conditions and prove that any limit point of the solution sequence is a stationary point. Finally, we validate the effectiveness of our algorithms through several numerical simulations.