Boundary behavior of optimal polynomial approximants

Abstract

In this paper, we provide an efficient method for computing the Taylor coefficients of 1-pn f, where pn denotes the optimal polynomial approximant of degree n to 1/f in a Hilbert space H2ω of analytic functions over the unit disc D, and f is a polynomial of degree d with d simple zeros. As a consequence, we show that in many of the spaces H2ω, the sequence \1-pnf\n∈ N is uniformly bounded on the closed unit disc and, if f has no zeros inside D, the sequence \1-pnf \ converges uniformly to 0 on compact subsets of the complement of the zeros of f in D, and we obtain precise estimates on the rate of convergence on compacta. We also treat the previously unknown case of a single zero with higher multiplicity.