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Admissible Majorants for Model Subspaces of H2, Part II: Fast Winding of the Generating Inner Function

Published online by Cambridge University Press:  20 November 2018

Victor Havin
Affiliation:
Department of Mathematics and Statistics, McGill University, Montreal, Quebec, H3A 2K6 e-mail: havin@havin.usr.pu.ru Department of Mathematics and Mechanics, St. Petersburg State University, Russia 198904
Javad Mashreghi
Affiliation:
Département de mathématiques et de statistique, Université Laval, Laval, Québec, G1K 7P4 e-mail: Javad.Mashreghi@mat.ulaval.ca
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Abstract

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This paper is a continuation of $[6]$. We consider the model subspaces ${{K}_{\Theta }}={{H}^{2}}\ominus \Theta {{H}^{2}}$ of the Hardy space ${{H}^{2}}$ generated by an inner function $\Theta $ in the upper half plane. Our main object is the class of admissible majorants for ${{K}_{\Theta }}$, denoted by Adm $\Theta $ and consisting of all functions $\omega $ defined on $\mathbb{R}$ such that there exists an $f\ne 0,f\in {{K}_{\Theta }}$ satisfying $|f\left( x \right)|\,\le \,\omega \left( x \right)$ almost everywhere on $\mathbb{R}$. Firstly, using some simple Hilbert transform techniques, we obtain a general multiplier theorem applicable to any ${{K}_{\Theta }}$ generated by a meromorphic inner function. In contrast with $[6]$, we consider the generating functions $\Theta $ such that the unit vector $\Theta \left( x \right)$ winds up fast as $x$ grows from $-\infty \,\text{to}\,\infty $. In particular, we consider $\Theta \,=\,B$ where $B$ is a Blaschke product with “horizontal” zeros, i.e., almost uniformly distributed in a strip parallel to and separated from $\mathbb{R}$. It is shown, among other things, that for any such $B$, any even $\omega $ decreasing on $\left( 0,\,\infty \right)$ with a finite logarithmic integral is in Adm $B$ (unlike the “vertical” case treated in $[6]$), thus generalizing (with a new proof) a classical result related to Adm $\exp \left( i\sigma z \right),\,\sigma \,>\,0$. Some oscillating $\omega $'s in Adm $B$ are also described. Our theme is related to the Beurling-Malliavin multiplier theorem devoted to Adm $\exp \left( i\sigma z \right),\,\sigma \,>\,0$, and to de Branges’ space $H\left( E \right)$.

Type
Research Article
Copyright
Copyright © Canadian Mathematical Society 2003

References

[1] Beurling, A. and Malliavin, P., On Fourier transforms of measures with compact support. Acta Math. 107(1962), 291309.Google Scholar
[2] Bary, N. and Steckin, S., Best approximation and differential properties of two conjugate function. Trudy Moskov. Mat. Obshch. 5(1956), 483522.Google Scholar
[3] Duren, P., Theory of Hp Spaces. Academic Press, 1970.Google Scholar
[4] Dyakonov, K., On the moduli and arguments of analytic functions of Hp that are invariant for the backward shift operator. Sibrisk. Mat. Zh. 31(1990), 6479.Google Scholar
[5] Havin, V. and Jöricke, B., The Uncertainty Principle in Harmonic Analysis. Springer-Verlag, 1994.Google Scholar
[6] Havin, V. and Mashreghi, Javad, Admissible majorants for model subspaces of H 2 , Part I: slowly winding of the generating inner function. Canad. J. Math. 55(2003), 12311263.Google Scholar
[7] Koosis, P., Leçons sur le Théorème de Beurling et Malliavin. Les Publications CRM, Montr éal, 1996.Google Scholar
[8] Koosis, P., Introduction to Hp Spaces. Cambridge Tracts in Math. 115, Second Edition, 1998.Google Scholar
[9] Koosis, P., The Logarithmic Integral I. Cambridge Stud. Adv. Math. 12, 1988.Google Scholar
[10] Koosis, P., The Logarithmic Integral II. Cambridge Stud. Adv. Math. 21, 1992.Google Scholar
[11] Levin, B., Distribution of zeros of Entire Functions. Transl. Math. Monogr. 5, 1980, Amer. Math. Soc.Google Scholar
[12] Privalov, I. I., Intégral de Cauchy. Bulletin de l'Universit é, à Saratov, 1918.Google Scholar
[13] Titchmarsh, E., Introduction to the Theory of Fourier Integrals. Chelsea Publishing Company, 1962.Google Scholar
[14] Zygmund, A., Trigonometric Series. Vol. I, Cambridge University Press, 1968.Google Scholar