# $l_{p}$-norms of Fourier coefficients of powers of a Blaschke factor

**Authors:** Oleg Szehr, Rachid Zarouf

arXiv: 1701.02358 · 2021-03-04

## TL;DR

This paper analyzes the asymptotic behavior of the $l_{p}$-norms of Taylor coefficients of powers of a Blaschke factor, extending known bounds to a broader range of p and establishing sharp asymptotics.

## Contribution

It extends the asymptotic bounds of $l_{p}$-norms for powers of Blaschke factors to the range p in [1,4) and provides sharp estimates for p > 4, including the critical case p=4.

## Key findings

- Extended bounds for $l_{p}$-norms to p in [1,4)
- Derived sharp asymptotic estimates for $p>4$
- Established the asymptotic sharpness of the bounds

## Abstract

We determine the asymptotic behavior of the $l_{p}$-norms of the sequence of Taylor coefficients of $b^{n}$, where $b=\frac{z-\lambda}{1-\bar{\lambda}z}$ is an automorphism of the unit disk, $p\in[1,\infty]$, and $n$ is large. It is known that in the parameter range $p\in[1,2]$ a sharp upper bound \begin{align*} \left|\!\left|b^{n}\right|\!\right|_{l_{p}^A}\leq C_{p}n^{\frac{2-p}{2p}} \end{align*} holds. In this article we find that this estimate is valid even when $p\in[1,4)$. We prove that \begin{align*} \left|\!\left|b^{n}\right|\!\right|_{l_{4}^A}\leq C_{4}\left(\frac{\log n}{n}\right)^{\frac{1}{4}} \end{align*} and for $p\in(4,\infty]$ that \begin{align*} \left|\!\left|b^{n}\right|\!\right|_{l_{p}^A}\leq C_{p}n^{\frac{1-p}{3p}} & . \end{align*} We prove that our upper bounds are sharp as $n$ tends to $\infty$ i.e. they have the correct asymptotic $n$ dependence.

## Full text

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## Figures

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## References

15 references — full list in the complete paper: https://tomesphere.com/paper/1701.02358/full.md

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Source: https://tomesphere.com/paper/1701.02358