Interpolation of holomorphic functions and surjectivity of Taylor coefficient multipliers

Multipliers on vector spaces of holomorphic functions

Nagoya Mathematical Journal ◽

10.1017/s0027763000007467 ◽

2000 ◽

Vol 159 ◽

pp. 167-178 ◽

Cited By ~ 2

Author(s):

Hermann Render ◽

Andreas Sauer

Keyword(s):

Uniqueness Theorem ◽

Complex Plane ◽

Hadamard Product ◽

Holomorphic Functions ◽

Vector Spaces ◽

Spaces Of Holomorphic Functions ◽

Coefficient Multipliers ◽

Multiplier Algebras

Let G be a domain in the complex plane containing zero and H(G) be the set of all holomorphic functions on G. In this paper the algebra M(H(G)) of all coefficient multipliers with respect to the Hadamard product is studied. Central for the investigation is the domain introduced by Arakelyan which is by definition the union of all sets with w ∈ Gc. The main result is the description of all isomorphisms between these multipliers algebras. As a consequence one obtains: If two multiplier algebras M(H(G1)) and M(H(G2)) are isomorphic then is equal to Two algebras H(G1) and H(G2) are isomorphic with respect to the Hadamard product if and only if G1 is equal to G2. Further the following uniqueness theorem is proved: If G1 is a domain containing 0 and if M(H(G)) is isomorphic to H(G1) then G1 is equal to .

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Boundary Schwarz lemma for holomorphic functions

Filomat ◽

10.2298/fil1718553o ◽

2017 ◽

Vol 31 (18) ◽

pp. 5553-5565

Author(s):

Nafi Örnek ◽

Burcu Gök

Keyword(s):

Boundary Point ◽

Unit Disc ◽

Holomorphic Functions ◽

Schwarz Lemma ◽

Angular Derivative ◽

Taylor Coefficient ◽

Boundary Schwarz Lemma ◽

Boundary Version

In this paper, a boundary version of Schwarz lemma is investigated. We take into consideration a function f (z) holomorphic in the unit disc and f (0) = 0 such that ?Rf? < 1 for ?z? < 1, we estimate a modulus of angular derivative of f (z) function at the boundary point b with f (b) = 1, by taking into account their first nonzero two Maclaurin coefficients. Also, we shall give an estimate below ?f'(b)? according to the first nonzero Taylor coefficient of about two zeros, namely z=0 and z0 ? 0. Moreover, two examples for our results are considered.

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Complex Analysis in Banach Spaces - Holomorphic Functions and Domains of Holomorphy in Finite and Infinite Dimensions

10.1016/s0304-0208(08)x7050-1 ◽

1986 ◽

Keyword(s):

Banach Spaces ◽

Complex Analysis ◽

Holomorphic Functions ◽

Infinite Dimensions ◽

Domains Of Holomorphy

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On the variability of the Priestley‐Taylor coefficient over water bodies

Water Resources Research ◽

10.1002/2015wr017504 ◽

2016 ◽

Vol 52 (1) ◽

pp. 150-163 ◽

Cited By ~ 23

Author(s):

Shmuel Assouline ◽

Dan Li ◽

Scott Tyler ◽

Josef Tanny ◽

Shabtai Cohen ◽

...

Keyword(s):

Water Bodies ◽

Taylor Coefficient

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A normal criterion of families of holomorphic functions

Analysis and Mathematical Physics ◽

10.1007/s13324-021-00539-8 ◽

2021 ◽

Vol 11 (3) ◽

Author(s):

Peiyan Niu ◽

Yan Xu

Keyword(s):

Holomorphic Functions ◽

Normal Criterion

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Mean ergodic composition operators on spaces of holomorphic functions on a Banach space

Journal of Mathematical Analysis and Applications ◽

10.1016/j.jmaa.2021.125139 ◽

2021 ◽

Vol 500 (2) ◽

pp. 125139

Author(s):

David Jornet ◽

Daniel Santacreu ◽

Pablo Sevilla-Peris

Keyword(s):

Banach Space ◽

Composition Operators ◽

Holomorphic Functions ◽

Spaces Of Holomorphic Functions

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Holomorphic functions with large cluster sets

Mathematische Nachrichten ◽

10.1002/mana.201900238 ◽

2021 ◽

Author(s):

Thiago R. Alves ◽

Daniel Carando

Keyword(s):

Holomorphic Functions ◽

Large Cluster ◽

Cluster Sets

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The Uniformisation of the Equation $$z^w=w^z$$

Computational Methods and Function Theory ◽

10.1007/s40315-021-00369-6 ◽

2021 ◽

Author(s):

A. F. Beardon

Keyword(s):

Positive Solutions ◽

Complex Plane ◽

Complex Variable ◽

Holomorphic Functions ◽

Parametric Form ◽

Lambert Function ◽

The Real ◽

Complex Equation ◽

Real Equation ◽

Expository Paper

AbstractThe positive solutions of the equation $$x^y = y^x$$ x y = y x have been discussed for over two centuries. Goldbach found a parametric form for the solutions, and later a connection was made with the classical Lambert function, which was also studied by Euler. Despite the attention given to the real equation $$x^y=y^x$$ x y = y x , the complex equation $$z^w = w^z$$ z w = w z has virtually been ignored in the literature. In this expository paper, we suggest that the problem should not be simply to parametrise the solutions of the equation, but to uniformize it. Explicitly, we construct a pair z(t) and w(t) of functions of a complex variable t that are holomorphic functions of t lying in some region D of the complex plane that satisfy the equation $$z(t)^{w(t)} = w(t)^{z(t)}$$ z ( t ) w ( t ) = w ( t ) z ( t ) for t in D. Moreover, when t is positive these solutions agree with those of $$x^y=y^x$$ x y = y x .

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Coefficients problems for families of holomorphic functions related to hyperbola

Mathematica Slovaca ◽

10.1515/ms-2017-0375 ◽

2020 ◽

Vol 70 (3) ◽

pp. 605-616

Author(s):

Stanisława Kanas ◽

Vali Soltani Masih ◽

Ali Ebadian

Keyword(s):

Unit Disk ◽

Holomorphic Functions ◽

Hankel Determinant ◽

Coefficient Problem

AbstractWe consider a family of analytic and normalized functions that are related to the domains ℍ(s), with a right branch of a hyperbolas H(s) as a boundary. The hyperbola H(s) is given by the relation $\begin{array}{} \frac{1}{\rho}=\left( 2\cos\frac{\varphi}{s}\right)^s\quad (0 \lt s\le 1,\, |\varphi| \lt (\pi s)/2). \end{array}$ We mainly study a coefficient problem of the families of functions for which zf′/f or 1 + zf″/f′ map the unit disk onto a subset of ℍ(s) . We find coefficients bounds, solve Fekete-Szegö problem and estimate the Hankel determinant.

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Slice holomorphic solutions of some directional differential equations with bounded L-index in the same direction

Demonstratio Mathematica ◽

10.1515/dema-2019-0043 ◽

2019 ◽

Vol 52 (1) ◽

pp. 482-489 ◽

Cited By ~ 1

Author(s):

Andriy Bandura ◽

Oleh Skaskiv ◽

Liana Smolovyk

Keyword(s):

Partial Differential Equations ◽

Continuous Function ◽

Differential Equations ◽

Sufficient Conditions ◽

Holomorphic Functions ◽

Positive Continuous Function ◽

Partial Differential ◽

Partial Derivatives ◽

Fixed Direction

AbstractIn the paper we investigate slice holomorphic functions F : ℂn → ℂ having bounded L-index in a direction, i.e. these functions are entire on every slice {z0 + tb : t ∈ℂ} for an arbitrary z0 ∈ℂn and for the fixed direction b ∈ℂn \ {0}, and (∃m0 ∈ ℤ+) (∀m ∈ ℤ+) (∀z ∈ ℂn) the following inequality holds{{\left| {\partial _{\bf{b}}^mF(z)} \right|} \over {m!{L^m}(z)}} \le \mathop {\max }\limits_{0 \le k \le {m_0}} {{\left| {\partial _{\bf{b}}^kF(z)} \right|} \over {k!{L^k}(z)}},where L : ℂn → ℝ+ is a positive continuous function, {\partial _{\bf{b}}}F(z) = {d \over {dt}}F\left( {z + t{\bf{b}}} \right){|_{t = 0}},\partial _{\bf{b}}^pF = {\partial _{\bf{b}}}\left( {\partial _{\bf{b}}^{p - 1}F} \right)for p ≥ 2. Also, we consider index boundedness in the direction of slice holomorphic solutions of some partial differential equations with partial derivatives in the same direction. There are established sufficient conditions providing the boundedness of L-index in the same direction for every slie holomorphic solutions of these equations.

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