Exact Constants in Inequalities for the Taylor Coefficients of Bounded Holomorphic Functions in a Polydisk

For 0 < p < ∞ and 0 ≤a; ≤ 1, we define a space Hp, a of holomorphic functions on the unit disc of the complex plane, for which Hp, 0 = H∞, the space of all bounded holomorphic functions, and Hp, 1 = Hp, the usual Hardy space. We introduce a weak type operator whose boundedness extends the well-known Hardy-Littlewood embedding theorem to Hp, a, give some results on the Taylor coefficients of the functions of Hp, a and show by an example that the inner factor cannot be divisible in Hp, a.

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DENSE STABLE RANK AND RUNGE-TYPE APPROXIMATION THEOREMS FOR MAPS

Journal of the Australian Mathematical Society ◽

10.1017/s1446788721000045 ◽

2021 ◽

pp. 1-29

Author(s):

ALEXANDER BRUDNYI

Keyword(s):

Disjoint Union ◽

A Priori ◽

Holomorphic Functions ◽

Stable Rank ◽

Open Unit ◽

Uniform Estimates ◽

Approximation Theorems ◽

Type Approximation ◽

Similar Approximation ◽

Bounded Holomorphic

Abstract Let $H^\infty ({\mathbb {D}}\times {\mathbb {N}})$ be the Banach algebra of bounded holomorphic functions defined on the disjoint union of countably many copies of the open unit disk ${\mathbb {D}}\subset {{\mathbb C}}$ . We show that the dense stable rank of $H^\infty ({\mathbb {D}}\times {\mathbb {N}})$ is $1$ and, using this fact, prove some nonlinear Runge-type approximation theorems for $H^\infty ({\mathbb {D}}\times {\mathbb {N}})$ maps. Then we apply these results to obtain a priori uniform estimates of norms of approximating maps in similar approximation problems for the algebra $H^\infty ({\mathbb {D}})$ .

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Angular and Tangential Limits of Blaschke Products and their Successive Derivatives

Canadian Journal of Mathematics ◽

10.4153/cjm-1962-026-2 ◽

1962 ◽

Vol 14 ◽

pp. 334-348 ◽

Cited By ~ 16

Author(s):

G. T. Cargo

Keyword(s):

Blaschke Product ◽

Common Knowledge ◽

Holomorphic Functions ◽

Blaschke Products ◽

Radial Limit ◽

Radial Limits ◽

Almost Everywhere ◽

Image Position ◽

Bounded Holomorphic ◽

Tangential Limits

In this paper, we shall be concerned with bounded, holomorphic functions of the formwhere(1)(2)and(3)B(z{an}) is called a Blaschke product, and any sequence {an} which satisfies (2) and (3) is called a Blaschke sequence. For a general discussion of the properties of Blaschke products, see (18, pp. 271-285) or (14, pp. 49-52).According to a theorem due to Riesz (15), a Blaschke product has radial limits of modulus one almost everywhere on C = {z: |z| = 1}. Moreover, it is common knowledge that, if a Blaschke product has a radial limit at a point, then it also has an angular limit at the point (see 14, p. 19 and 6, p. 457).

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Extending bounded holomorphic functions from certain subvarieties of a polydisc

Pacific Journal of Mathematics ◽

10.2140/pjm.1969.29.485 ◽

1969 ◽

Vol 29 (3) ◽

pp. 485-490 ◽

Cited By ~ 11

Author(s):

Herbert Alexander

Keyword(s):

Holomorphic Functions ◽

Bounded Holomorphic

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Admissible boundary values of bounded holomorphic functions in wedges

Transactions of the American Mathematical Society ◽

10.1090/s0002-9947-1992-1087055-9 ◽

1992 ◽

Vol 332 (2) ◽

pp. 583-593 ◽

Cited By ~ 2

Author(s):

Franc Forstnerič

Keyword(s):

Holomorphic Functions ◽

Boundary Values ◽

Bounded Holomorphic

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A NOTE ON ZEROS OF BOUNDED HOLOMORPHIC FUNCTIONS IN WEAKLY PSEUDOCONVEX DOMAINS IN ℂ2

Bulletin of the Korean Mathematical Society ◽

10.4134/bkms.b160429 ◽

2017 ◽

Vol 54 (3) ◽

pp. 993-1002

Author(s):

Ly Kim Ha

Keyword(s):

Holomorphic Functions ◽

Pseudoconvex Domains ◽

Weakly Pseudoconvex ◽

Bounded Holomorphic

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Dual Algebras and A-Measures

Journal of Function Spaces ◽

10.1155/2014/364271 ◽

2014 ◽

Vol 2014 ◽

pp. 1-8

Author(s):

Marek Kosiek ◽

Krzysztof Rudol

Keyword(s):

Analytic Functions ◽

Complete Solution ◽

Holomorphic Functions ◽

Classical Case ◽

Function Algebra ◽

Domain Of Holomorphy ◽

Strict Pseudoconvexity ◽

Weak Star ◽

Spectrum Of A Function ◽

Bounded Holomorphic

Weak-star closures of Gleason parts in the spectrum of a function algebra are studied. These closures relate to the bidual algebra and turn out both closed and open subsets of a compact hyperstonean space. Moreover, weak-star closures of the corresponding bands of measures are reducing. Among the applications we have a complete solution of an abstract version of the problem, whether the set of nonnegative A-measures (called also Henkin measures) is closed with respect to the absolute continuity. When applied to the classical case of analytic functions on a domain of holomorphyΩ⊂Cn, our approach avoids the use of integral formulae for analytic functions, strict pseudoconvexity, or some other regularity ofΩ. We also investigate the relation between the algebra of bounded holomorphic functions onΩand its abstract counterpart—thew* closure of a function algebraAin the dual of the band of measures generated by one of Gleason parts of the spectrum ofA.

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Chapter V - Spaces of Bounded Holomorphic Functions

Saks Spaces and Applications to Functional Analysis - North-Holland Mathematics Studies ◽

10.1016/s0304-0208(08)70256-1 ◽

1978 ◽

pp. 225-266

Keyword(s):

Holomorphic Functions ◽

Bounded Holomorphic

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Holomorphic functions with distinguished properties on infinite dimensional spaces

The Quarterly Journal of Mathematics ◽

10.1093/qmath/hay065 ◽

2018 ◽

Vol 70 (3) ◽

pp. 797-811

Author(s):

Thiago R Alves ◽

Geraldo Botelho

Keyword(s):

Banach Space ◽

Holomorphic Functions ◽

Complex Banach Space ◽

Algebraic Structures ◽

Infinite Dimensional ◽

Zero Function ◽

Bounded Holomorphic

Abstract In this paper, we develop a method to construct holomorphic functions that exist only on infinite dimensional spaces. The following types of holomorphic functions f:U→ℂ on some open subsets U of an infinite dimensional complex Banach space are constructed: (1) f is bounded holomorphic on U and is continuously, but not uniformly continuously extended to U¯; (2) f is continuous on U¯ and holomorphic of bounded type on U, but f is unbounded on U; (3) f is holomorphic of bounded type on U and f cannot be continuously extended to U¯. The technique we develop is powerful enough to provide, in the cases (2) and (3) above, large algebraic structures formed by such functions (up to the zero function, of course).

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The Maximal Ideal Space of H∞ + C on the ball in Cn

Canadian Journal of Mathematics ◽

10.4153/cjm-1979-009-6 ◽

1979 ◽

Vol 31 (1) ◽

pp. 79-86 ◽

Cited By ~ 8

Author(s):

Gerard Mcdonald

Keyword(s):

Maximal Ideal ◽

Banach Algebras ◽

Holomorphic Functions ◽

Maximal Ideal Space ◽

Open Unit ◽

Ideal Space ◽

Open Unit Ball ◽

Closed Subalgebra ◽

Image Position ◽

Bounded Holomorphic

Let S denote the unit sphere in Cn, B the (open) unit ball in Cn and H∞(B) the collection of all bounded holomorphic functions on B. For f ∈ H∞(B) the limitsexist for almost every ζ in S, and the map ƒ → ƒ* defines an isometric isomorphism from H∞(B) onto a closed subalgebra of L∞(S), denoted H∞(S). (The only measure on S we will refer to in this paper is the Lebesgue measure, dσ, generated by Euclidean surface area.) Rudin has shown in [4] that the spaces H∞(B) + C(B) and H∞(S) + C(S) are Banach algebras in the sup norm. In this paper we will show that the maximal ideal space of H∞(B) + C(B), Σ (H∞(B) + C(B)), is naturally homeomorphic to Σ (H∞(B)) and that Z (H∞(S) + C(S)) is naturally homeomorphic to Σ (H∞(S))\B.

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