Fejer Polynomials and Control of Nonlinear Discrete Systems

Abstract

We consider optimization problems associated to a delayed feedback control (DFC) mechanism for stabilizing cycles of one dimensional discrete time systems. In particular, we consider a delayed feedback control for stabilizing T-cycles of a differentiable function f: R→R of the form x(k+1) = f(x(k)) + u(k) where u(k) = (a1 - 1)f(x(k)) + a2 f(x(k-T)) + ·s + aN f(x(k-(N-1)T))\;, with a1 + ·s + aN = 1. Following an approach of Morg\"ul, we associate to each periodic orbit of f, N ∈ N, and a1,…,aN an explicit polynomial whose Schur stability corresponds to the stability of the DFC on that orbit. We prove that, given any 1- or 2-cycle of f, there exist N and a1,…,aN whose associated polynomial is Schur stable, and we find the minimal N that guarantees this stabilization. The techniques of proof will take advantage of extremal properties of the Fej\'er kernels found in classical harmonic analysis.