Invertible and normal composition operators on the Hilbert Hardy space of a half–plane

Matache, Valentin

doi:10.1515/conop-2016-0009

Cited by 11 publications

(15 citation statements)

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“…Proof of (3); since C is bounded and Hermitian ' is continuous on the closed unit disc (see Theorem B). Since 0 exist at p we let z D p in (8). Then r D ' 0 .p/: From part (6) of Lemma 4.1 it follows that ' 0 .p/ D 1:…”

Section: Hermitian Operatorsmentioning

confidence: 99%

“…To prove (2) let z D p in (8). Proof of (3); since C is bounded and Hermitian ' is continuous on the closed unit disc (see Theorem B).…”

Section: Hermitian Operatorsmentioning

confidence: 99%

“…/ are studied in [10]. Also, composition operators on a Hardy space of a half-plane are studied in [7], [8], and [9]. In this paper we study bounded Hermitian composition operators on H 2 .…”

Section: Introductionmentioning

confidence: 99%

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Hermitian composition operators on Hardy-Smirnov spaces

Gunatillake

2017

Concrete Operators

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Abstract:Let be an open simply connected proper subset of the complex plane and an analytic self map of . If f is in the Hardy-Smirnov space defined on , then the operator that takes f to f ı is a composition operator. We show that for any , analytic self maps that induce bounded Hermitian composition operators are of the form .w/ D aw C b where a is a real number. For ceratin , we completely describe values of a and b that induce bounded Hermitian composition operators.

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Section: Hermitian Operatorsmentioning

confidence: 99%

“…To prove (2) let z D p in (8). Proof of (3); since C is bounded and Hermitian ' is continuous on the closed unit disc (see Theorem B).…”

Section: Hermitian Operatorsmentioning

confidence: 99%

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Hermitian composition operators on Hardy-Smirnov spaces

Gunatillake

2017

Concrete Operators

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“…Composition operators C τ : f → f • τ , where τ : Π + −→ Π + is analytic, acting on these spaces are, however, much less studied when compared to their counterparts in the unit disc setting. Matache [12] found a condition for boundedness of C τ on H 2 (Π + ) in terms of Carleson measures and showed later in [13] that there are no compact composition operators on H 2 (Π + ). In [22] Shapiro and Smith extended the non-compactness result to A 2 α (Π + ).…”

Section: Introductionmentioning

confidence: 99%

“…In fact, in the unit disc setting the spectral picture of composition operators has been completely determined when the inducing maps are linear fractional transformations and the operators act on weighted Dirichlet spaces, including H 2 (D) and A 2 α (D) for all α > −1 (see, for instance, [17,2,10,8,19,7]). The spectra in the corresponding setting on the half-plane are largely unknown; in the (unweighted) Dirichlet space of Π + the spectra are known but besides that only the spectra (and the essential spectra) for invertible or self-adjoint parabolic and invertible hyperbolic composition operators acting on the Hardy space H 2 (Π + ) have been computed (see [15]). In contrast to the unit disc case, not all linear fractional transformations τ induce bounded composition operators on H 2 (Π + ) or A 2 α (Π + ).…”

Section: Introductionmentioning

confidence: 99%

Spectra of linear fractional composition operators on the Hardy and weighted Bergman spaces of the half-plane

Schroderus

2017

Journal of Mathematical Analysis and Applications

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Abstract. We compute the spectra and the essential spectra of bounded linear fractional composition operators acting on the Hardy and weighted Bergman spaces of the upper halfplane. We are also able to extend the results to weighted Dirichlet spaces of the upper halfplane. IntroductionThe Boundedness of a composition operator C τ on the Hardy or the weighted Bergman spaces of the half-plane has been proved to be equivalent with the angular derivative of the inducing map at infinity, denoted by τ ′ (∞), being finite and positive (see [14,6]). In addition, Elliott et al. [6,5] have shown that whenever C τ is bounded, the operator norm, the essential operator norm and the spectral radius are all equal and determined by the quantity τ ′ (∞). The above properties show that the spaces H 2 (Π + ) and A 2 α (Π + ) differ significantly from their unit disc analogues H 2 (D) and A 2 α (D) regarding the composition operators acting on them. We refer e.g. to [21,2] for expositions of the rich theory of composition operators on spaces defined on the unit disc.It is natural to ask what the spectral properties of composition operators acting on the halfplane are. In fact, in the unit disc setting the spectral picture of composition operators has been completely determined when the inducing maps are linear fractional transformations and the operators act on weighted Dirichlet spaces, including H 2 (D) and A 2 α (D) for all α > −1 (see, for instance, [17,2,10,8,19,7]). The spectra in the corresponding setting on the half-plane are largely unknown; in the (unweighted) Dirichlet space of Π + the spectra are known but besides that only the spectra (and the essential spectra) for invertible or self-adjoint parabolic and invertible hyperbolic composition operators acting on the Hardy space H 2 (Π + ) have been computed (see [15]). In contrast to the unit disc case, not all linear fractional transformations τ induce bounded composition operators on. Indeed, C τ is bounded only when τ is a parabolic or a hyperbolic self-map of Π + fixing infinity. In this paper we compute the spectra and the essential spectra of these composition operators.In the parabolic case (see Theorem 3.1 in Section 3) we obtain the following result:Theorem A. Let τ be a parabolic self-map of Π + , that is, τ (w) = w + w 0 , where Im w 0 ≥ 0 and w 0 = 0. Then the spectrum of C τ acting on the Hardy or the weighted Bergman spaces of the upper half-plane equals2010 Mathematics Subject Classification. 47B33. Key words and phrases. Composition operator, spectrum, essential spectrum, Hardy space of the upper halfplane, weighted Bergman spaces of the upper half-plane.The author is supported by the Magnus Ehrnrooth Foundation in Finland.

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An Invertibility Criterion in a C*-Algebra Acting on the Hardy Space with Applications to Composition Operators

Gül

Koca

2018

Mediterr. J. Math.

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In this paper we prove an invertibility criterion for certain operators which is given as a linear algebraic combination of Toeplitz operators and Fourier multipliers acting on the Hardy space of the unit disc. Very similar to the case of Toeplitz operators we prove that such operators are invertible if and only if they are Fredholm and their Fredholm index is zero. As an application we prove that for "quasi-parabolic" composition operators the spectra and the essential spectra are equal.2000 Mathematics Subject Classification. 47B33.

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Invertible and normal composition operators on the Hilbert Hardy space of a half–plane

Cited by 11 publications

References 6 publications

Hermitian composition operators on Hardy-Smirnov spaces

Hermitian composition operators on Hardy-Smirnov spaces

Spectra of linear fractional composition operators on the Hardy and weighted Bergman spaces of the half-plane

An Invertibility Criterion in a C*-Algebra Acting on the Hardy Space with Applications to Composition Operators

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