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Main Authors: Bouabdillah, Oualid, Merdy, Christian Le
Format: Preprint
Published: 2022
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Online Access:https://arxiv.org/abs/2203.05373
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author Bouabdillah, Oualid
Merdy, Christian Le
author_facet Bouabdillah, Oualid
Merdy, Christian Le
contents Let $T\colon X\to X$ be a bounded operator on Banach space, whose spectrum $σ(T)$ is included in the closed unit disc $\overline{\mathbb D}$. Assume that the peripheral spectrum $σ(T)\cap{\mathbb T}$ is finite and that $T$ satisfies a resolvent estimate $$\Vert(z-T)^{-1}\Vert\lesssim \max\bigl\{\vert z -ξ\vert^{-1}\, :\,ξ\in σ(T)\cap{\mathbb T}\bigr\}, \qquad z\in\overline{\mathbb D}^c.$$ We prove that $T$ admits a bounded polygonal functional calculus, that is, an estimate $\Vertϕ(T)\Vert\lesssim \sup\{\vertϕ(z)\vert\, :\, z\inΔ\}$ for some polygon $Δ\subset{\mathbb D}$ and all polynomials $ϕ$, in each of the following two cases : (i) either $X=L^p$ for some $1<p<\infty$, and $T\colon L^p\to L^p$ is a positive contraction; (ii) or $T$ is polynomially bounded and for all $ξ\in σ(T)\cap{\mathbb T},$ there exists a neighborhood $\mathcal V$ of $ξ$ such that the set $\{(ξ-z)(z-T)^{-1}\, :\, z\in{\mathcal V}\cap \overline{\mathbb D}^c\}$ is $R$-bounded (here $X$ is arbitrary). Each of these two results extends a theorem of de Laubenfels concerning polygonal functional calculus on Hilbert space. Our investigations require the introduction, for any finite set $E\subset{\mathbb T}$, of a notion of Ritt$_E$ operator which generalises the classical notion of Ritt operator. We study these Ritt$_E$ operators and their natural functional calculus.
format Preprint
id arxiv_https___arxiv_org_abs_2203_05373
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Polygonal functional calculus for operators with finite peripheral spectrum
Bouabdillah, Oualid
Merdy, Christian Le
Functional Analysis
Primary 47A60, secondary 47B12, 47B01
Let $T\colon X\to X$ be a bounded operator on Banach space, whose spectrum $σ(T)$ is included in the closed unit disc $\overline{\mathbb D}$. Assume that the peripheral spectrum $σ(T)\cap{\mathbb T}$ is finite and that $T$ satisfies a resolvent estimate $$\Vert(z-T)^{-1}\Vert\lesssim \max\bigl\{\vert z -ξ\vert^{-1}\, :\,ξ\in σ(T)\cap{\mathbb T}\bigr\}, \qquad z\in\overline{\mathbb D}^c.$$ We prove that $T$ admits a bounded polygonal functional calculus, that is, an estimate $\Vertϕ(T)\Vert\lesssim \sup\{\vertϕ(z)\vert\, :\, z\inΔ\}$ for some polygon $Δ\subset{\mathbb D}$ and all polynomials $ϕ$, in each of the following two cases : (i) either $X=L^p$ for some $1<p<\infty$, and $T\colon L^p\to L^p$ is a positive contraction; (ii) or $T$ is polynomially bounded and for all $ξ\in σ(T)\cap{\mathbb T},$ there exists a neighborhood $\mathcal V$ of $ξ$ such that the set $\{(ξ-z)(z-T)^{-1}\, :\, z\in{\mathcal V}\cap \overline{\mathbb D}^c\}$ is $R$-bounded (here $X$ is arbitrary). Each of these two results extends a theorem of de Laubenfels concerning polygonal functional calculus on Hilbert space. Our investigations require the introduction, for any finite set $E\subset{\mathbb T}$, of a notion of Ritt$_E$ operator which generalises the classical notion of Ritt operator. We study these Ritt$_E$ operators and their natural functional calculus.
title Polygonal functional calculus for operators with finite peripheral spectrum
topic Functional Analysis
Primary 47A60, secondary 47B12, 47B01
url https://arxiv.org/abs/2203.05373