Proceedings of the American Mathematical Society

Author(s): Peter G. Casazza; Nigel J. Kalton
Journal: Proc. Amer. Math. Soc. 130 (2002), 2313-2318.
MSC (1991): Primary 30C15, 11C08, 42C15, 46C05
Posted: January 17, 2002
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Abstract: A Weyl-Heisenberg frame for $L^{2}(\mathbb R)$ is a frame consisting of modulates $E_{mb}g(t) = e^{2{\pi}imbt}g(t)$ and translates $T_{na}g(t) = g(t-na)$ , $m,n\in \mathbb Z$ , of a fixed function $g\in L^{2} (\mathbb R)$ , for $a,b\in \mathbb R$ . A fundamental question is to explicitly represent the families

so that $(E_{mb}T_{na}g)_{m,n\in \mathbb Z}$ is a frame for $L^{2}(\mathbb R)$ . We will show an interesting connection between this question and a classical problem of Littlewood in complex function theory. In particular, we show that classifying the characteristic functions ${\chi}_{E}$ for which $(E_{m}T_{n}{\chi}_{E})_{m,n\in \mathbb Z}$ is a frame for $L^{2}(\mathbb R)$ is equivalent to classifying the integer sets $\{n_{1}<n_{2}<\cdots <n_{k}\}$ so that $f(z) = \sum_{j=1}^{k} z^{n_{i}}$ does not have any zeroes on the unit circle in the plane.

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Retrieve articles in Proceedings of the American Mathematical Society with MSC (1991): 30C15, 11C08, 42C15, 46C05

Peter G. Casazza
Affiliation: Department of Mathematics, University of Missouri-Columbia, Columbia, Missouri 65211
Email: pete@math.missouri.edu

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