Keri Kornelson
University of Oklahoma
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Featured researches published by Keri Kornelson.
Archive | 2007
Deguang Han; Keri Kornelson; David R. Larson; Eric Weber
Introduction Linear algebra review Finite-dimensional operator theory Introduction to finite frames Frames in
arXiv: Operator Algebras | 2008
Palle E. T. Jorgensen; Keri Kornelson; Karen L. Shuman
\mathbb{R}^2
Journal of Mathematical Physics | 2007
Palle E. T. Jorgensen; Keri Kornelson; Karen L. Shuman
The dilation property of frames Dual and orthogonal frames Frame operator decompositions Harmonic and group frames Sampling theory Student presentations Anecdotes on frame theory projects by undergraduates Bibliography List of symbols Index.
Numerical Functional Analysis and Optimization | 2012
Palle E. T. Jorgensen; Keri Kornelson; Karen L. Shuman
We investigate certain spectral properties of the Bernoulli convolution measures on attractor sets arising from iterated function systems (IFSs) on ℝ. In particular, we examine collections of orthogonal exponential functions in the Hilbert space of square-integrable functions on the attractor. We carefully examine a test case λ = 3/4 in which the IFS has overlap. We also determine rational λ = a/b for which infinite sets of orthogonal exponentials exist.
Journal of Mathematical Physics | 2014
Palle E. T. Jorgensen; Keri Kornelson; Karen L. Shuman
An iterated function system (IFS) is a system of contractive mappings τi:Y→Y, i=1,…,N (finite), where Y is a complete metric space. Every such IFS has a unique (up to scale) equilibrium measure (also called the Hutchinson measure μ), and we study the Hilbert space L2(μ). In this paper we extend previous work on IFSs without overlap. Our method involves systems of operators generalizing the more familiar Cuntz relations from operator algebra theory and from subband filter operators in signal processing. These Cuntz-like operator systems were used in recent papers on wavelet analysis by Baggett, Jorgensen, Merrill, and Packer [Contemp. Math. 345, 11–25 (2004)], where they serve as a first step to generating wavelet bases of Parseval type (alias normalized tight frames), i.e., wavelet bases with redundancy. Similarly, it was shown in work by Dutkay and Jorgensen [Rev. Mat. Iberoam. 22, 131–180 (2006)] that the iterative operator approach works well for generating wavelets on fractals from IFSs without overla...
International Journal of Gaming and Computer-mediated Simulations | 2016
Scott N. Wilson; Javier Elizondo; Ryan Ralston; Yu-Hao Lee; Norah E. Dunbar; Keri Kornelson; Milos Savic; Sepideh Stewart; Emily Lennox; William Thompson
Certain Bernoulli convolution measures μ are known to be spectral. Recently, much work has concentrated on determining conditions under which orthonormal Fourier bases (i.e. spectral bases) exist. For a fixed measure known to be spectral, the ONB need not be unique; indeed, there are often families of such spectral bases. Let for a natural number n and consider the Bernoulli measure with scale factor λ. It is known that L 2(μλ) has a Fourier basis. We first show that there are Cuntz operators acting on this Hilbert space which create an orthogonal decomposition, thereby offering powerful algorithms for computations for Fourier expansions. When L 2(μλ) has more than one Fourier basis, there are natural unitary operators U, indexed by a subset of odd scaling factors p; each U is defined by mapping one ONB to another. We show that the unitary operator U can also be orthogonally decomposed according to the Cuntz relations. Moreover, this operator-fractal U exhibits its own self-similarity.
international conference on sampling theory and applications | 2015
Akram Aldroubi; Keri Kornelson
We examine the operator
Proceedings of SPIE | 2013
David C. Smith; Keri Kornelson
U_5
Canadian Journal of Mathematics | 2005
Keri Kornelson
defined on
Illinois Journal of Mathematics | 2004
Ken Dykema; Daniel Freeman; Keri Kornelson; David R. Larson; Marc Ordower; Eric Weber
L^2(\mu_{\frac14})