Sparsity-Promoting Optimal Control of Distributed Systems


Event Speaker: 

Mihailo Jovanovic (Univ. of Minnesota)

Event Location: 


Event Date/Time: 

Tuesday, November 6, 2012 - 4:00pm

Reception to follow.
This talk is about design of feedback gains that strike a balance between the quadratic performance of distributed systems and the sparsity of the controller. Our approach consists of two steps. First, we identify sparsity patterns of the feedback gains by incorporating sparsity-promoting penalty functions into the optimal control problem, where the added terms penalize the number of communication links in the distributed controller. Second, we optimize the feedback gains subject to the structural constraints determined by the identified sparsity patterns. In the first step, we identify sparsity patterns of the feedback gains using the alternating direction method of multipliers, which is an algorithm well-suited to large optimization problems. This method alternates between optimizing the sparsity and optimizing the closed-loop performance, which allows us to exploit the structure of the corresponding objective functions. In particular, we take advantage of the separability of the sparsity-promoting penalty functions to decompose the minimization problem into sub-problems that can be solved analytically. In the second step, we develop Newton's method in conjunction with the conjugate gradient scheme to efficiently compute the sparse feedback matrix. Several examples are provided to illustrate the effectiveness of the developed approach.
Mihailo R. Jovanovic is an Associate Professor of Electrical and Computer Engineering at the University of Minnesota, Minneapolis, where he also serves as the Director of Graduate Studies in the interdisciplinary Ph.D. program in Control Science and Dynamical Systems. He has held visiting positions with Stanford University and the Institute for Mathematics and its Applications. His current research focuses on sparsity-promoting optimal control, dynamics and control of fluid flows, and fundamental limitations in the design of large dynamic networks. He is a member of IEEE, APS, and SIAM and has served as an Associate Editor of the IEEE Control Systems Society Conference Editorial Board from July 2006 until December 2010. He received a CAREER Award from the National Science Foundation in 2007, an Early Career Award from the University of Minnesota Initiative for Renewable Energy and the Environment in 2010, and a Resident Fellowship within the Institute on the Environment at the University of Minnesota in 2012.