English

Cyclic inner functions in growth classes and applications to approximation problems

Complex Variables 2022-05-19 v2 Functional Analysis

Abstract

It is well-known that for any inner function θ\theta defined in the unit disk DD the following two conditons: (i)(i) there exists a sequence of polynomials {pn}n\{p_n\}_n such that limnθ(z)pn(z)=1\lim_{n \to \infty} \theta(z) p_n(z) = 1 for all zDz \in D, and (ii)(ii) supnθpn<\sup_n \| \theta p_n \|_\infty < \infty, are incompatible, i.e., cannot be satisfied simultaneously. In this note we discuss and apply a consequence of a result by Thomas Ransford, which shows that if we relax the second condition to allow for arbitrarily slow growth of the sequence {θ(z)pn(z)}n\{ \theta(z) p_n(z)\}_n as z1|z| \to 1, then condition (i)(i) can be met. In other words, every growth class of analytic functions contains cyclic singular inner functions. We apply this observation to properties of decay of Taylor coefficients and moduli of continuity of functions in model spaces KθK_\theta. In particular, we establish a variant of a result of Khavinson and Dyakonov on non-existence of functions with certain smoothness properties in KθK_\theta, and we show that the classical Aleksandrov theorem on density of continuous functions in KθK_\theta, and its generalization to de Branges-Rovnyak spaces H(b)\mathcal{H}(b), is essentially sharp.

Keywords

Cite

@article{arxiv.2205.01778,
  title  = {Cyclic inner functions in growth classes and applications to approximation problems},
  author = {Bartosz Malman},
  journal= {arXiv preprint arXiv:2205.01778},
  year   = {2022}
}

Comments

This is a first version of the paper. Some updates are likely in near future. Any comments are highly appreciated

R2 v1 2026-06-24T11:06:27.857Z