Calafiore, Giuseppe (Pol. di Torino)

Cutting Plane Methods for Probabilistically-Robust Feasibility Problems

Scheduled for presentation during the Mini-Symposium "Randomized and Probabilistic Techniques for Complex Systems Design" (MoP08), Monday, July 24, 2006, 16:35−17:00, Room I

17th International Symposium on Mathematical Theory of Networks and Systems, July 24-28, 2006, Kyoto, Japan

This information is tentative and subject to change. Compiled on April 20, 2024

Abstract

Many robust control problems can be formulated in abstract form as convex feasibility programs where one seeks a solution vector x that satisfies a set of inequalities of the form F={f(x,delta) <= 0}. This set typically contains an infinite and uncountable number of inequalities, and it has been proved that the related robust feasibility problem is numerically hard to solve in general. In this paper, we discuss a family of cutting plane methods that solve efficiently a probabilistically-relaxed version of the problem. Specifically, under suitable hypotheses, we show that a cutting plane scheme based on a probabilistic oracle returns in a finite and pre-specified number of iterations a solution which is feasible for most of the members of F, except possibly for a subset having arbitrarily small probability measure.