Ten lectures on wavelets
The wavelet transform, time-frequency localization and signal analysis
IEEE Transactions on Information Theory
On the density of phase-space expansions
IEEE Transactions on Information Theory
Homogeneous approximation property for continuous wavelet transforms
Journal of Approximation Theory
Neurocomputing
Comparison theorems for separable wavelet frames
Journal of Approximation Theory
Model space results for the Gabor and wavelet transforms
IEEE Transactions on Information Theory
Duals of Weighted Exponential Systems
Acta Applicandae Mathematicae: an international survey journal on applying mathematics and mathematical applications
Hi-index | 0.06 |
An irregular wavelet frame has the form W(@j,@L)={a^-^1^/^2@j(xa-b)}"("a","b")"@?"@L, where @j@?L^2(R) and @L is an arbitrary sequence of points in the affine group A=R^+xR. Such irregular wavelet frames are poorly understood, yet they arise naturally, e.g., from sampling theory or the inevitability of perturbations. This paper proves that irregular wavelet frames satisfy a Homogeneous Approximation Property, which essentially states that the rate of approximation of a wavelet frame expansion of a function f is invariant under time-scale shifts of f, even though @L is not required to have any structure-it is only required that the wavelet @j has a modest amount of time-scale concentration. It is shown that the Homogeneous Approximation Property has several implications on the geometry of @L, and in particular a relationship between the affine Beurling density of the frame and the affine Beurling density of any other Riesz basis of wavelets is derived. This further yields necessary conditions for the existence of wavelet frames, and insight into the fundamental question of why there is no Nyquist density phenomenon for wavelet frames, as there is for Gabor frames that are generated from time-frequency shifts.