Saved in:
Bibliographic Details
Main Author: Chen, Gangqiang
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2404.09965
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866914755386540032
author Chen, Gangqiang
author_facet Chen, Gangqiang
contents Let ${\mathcal S}$ be the class of analytic functions $f$ in the unit disk ${\mathbb D}$ with $f({\mathbb D}) \subset \overline{\mathbb D}$. Fix pairwise distinct points $z_1,\ldots,z_{n+1}\in \mathbb{D}$ and corresponding interpolation values $w_1,\ldots,w_{n+1}\in \overline{\mathbb{D}}$. Suppose that $f\in{\mathcal S}$ and $f(z_j)=w_j$, $j=1,\ldots,n+1$. Then for each fixed $z \in {\mathbb D} \backslash \{z_1,\ldots,z_{n+1} \}$, we obtained a multi-point Schwarz-Pick Lemma, which determines the region of values of $f(z)$. Using an improved Schur algorithm in terms of hyperbolic divided differences, we solve a Schur interpolation problem involving a fixed point together with the hyperbolic derivatives up to a certain order at the point, which leads to a new interpretation to a generalized Rogosinski's Lemma. For each fixed $z_0 \in {\mathbb D}$, $j=1,2, \ldots n$ and $γ= (γ_0, γ_1 , \ldots , γ_n) \in {\mathbb D}^{n+1}$, denote by $H^jf(z)$ the hyperbolic derivative of order $j$ of $f$ at the point $z\in {\mathbb D}$, let ${\mathcal S} (γ) = \{f \in {\mathcal S} : f (z_0) = γ_0,H^1f (z_0) = γ_1,\ldots ,H^nf (z_0) = γ_n \}$. We determine the region of variability $V(z, γ) = \{ f(z) : f \in {\mathcal S} (γ) \}$ for $z\in {\mathbb D} \backslash \{ z_0 \}$, which can be called "the generalized Rogosinski-Pick Lemma for higher-order hyperbolic derivatives".
format Preprint
id arxiv_https___arxiv_org_abs_2404_09965
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Variability regions for Schur class
Chen, Gangqiang
Complex Variables
30F45, 30C80
Let ${\mathcal S}$ be the class of analytic functions $f$ in the unit disk ${\mathbb D}$ with $f({\mathbb D}) \subset \overline{\mathbb D}$. Fix pairwise distinct points $z_1,\ldots,z_{n+1}\in \mathbb{D}$ and corresponding interpolation values $w_1,\ldots,w_{n+1}\in \overline{\mathbb{D}}$. Suppose that $f\in{\mathcal S}$ and $f(z_j)=w_j$, $j=1,\ldots,n+1$. Then for each fixed $z \in {\mathbb D} \backslash \{z_1,\ldots,z_{n+1} \}$, we obtained a multi-point Schwarz-Pick Lemma, which determines the region of values of $f(z)$. Using an improved Schur algorithm in terms of hyperbolic divided differences, we solve a Schur interpolation problem involving a fixed point together with the hyperbolic derivatives up to a certain order at the point, which leads to a new interpretation to a generalized Rogosinski's Lemma. For each fixed $z_0 \in {\mathbb D}$, $j=1,2, \ldots n$ and $γ= (γ_0, γ_1 , \ldots , γ_n) \in {\mathbb D}^{n+1}$, denote by $H^jf(z)$ the hyperbolic derivative of order $j$ of $f$ at the point $z\in {\mathbb D}$, let ${\mathcal S} (γ) = \{f \in {\mathcal S} : f (z_0) = γ_0,H^1f (z_0) = γ_1,\ldots ,H^nf (z_0) = γ_n \}$. We determine the region of variability $V(z, γ) = \{ f(z) : f \in {\mathcal S} (γ) \}$ for $z\in {\mathbb D} \backslash \{ z_0 \}$, which can be called "the generalized Rogosinski-Pick Lemma for higher-order hyperbolic derivatives".
title Variability regions for Schur class
topic Complex Variables
30F45, 30C80
url https://arxiv.org/abs/2404.09965