English

A geometric approach to the cascade approximation operator for wavelets

Functional Analysis 2007-05-23 v1

Abstract

This paper is devoted to an approximation problem for operators in Hilbert space, that appears when one tries to study geometrically the cascade algorithm in wavelet theory. Let H H be a Hilbert space, and let π \pi be a representation of L(T) L^\infty(T) on H H . Let R R be a positive operator in L(T) L^\infty(T) such that R(1)=1 R(1)=1 , where 1 1 denotes the constant function 1 1 . We study operators M M on H H (bounded, but non-contractive) such that π(f)M=Mπ(f(z2)) \pi(f)M=M\pi(f(z^2)) and Mπ(f)M=π(Rf) M^* \pi(f)M=\pi(R^* f) , fL(T) f \in L^\infty (T) , where the * refers to Hilbert space adjoint. We give a complete orthogonal expansion of H H which reduces π \pi such that M M acts as a shift on one part, and the residual part is H()=n[MnH] H^{(\infty)}=\bigcap_n[M^n H] , where [MnH] [M^n H] is the closure of the range of Mn M^n . The shift part is present, we show, if and only if ker(M){0} \ker(M^*) \neq \{0\} . We apply the operator-theoretic results to the refinement operator (or cascade algorithm) from wavelet theory. Using the representation π \pi , we show that, for this wavelet operator M M , the components in the decomposition are unitarily, and canonically, equivalent to spaces L2(En)L2(R) L^2(E_n) \subset L^2(R) , where EnR E_n \subset R , n=0,1,2,..., n=0,1,2,...,\infty , are measurable subsets which form a tiling of R R ; i.e., the union is R R up to zero measure, and pairwise intersections of different En E_n 's have measure zero. We prove two results on the convergence of the cascade algorithm, and identify singular vectors for the starting point of the algorithm.

Keywords

Cite

@article{arxiv.math/9912132,
  title  = {A geometric approach to the cascade approximation operator for wavelets},
  author = {Palle E. T. Jorgensen},
  journal= {arXiv preprint arXiv:math/9912132},
  year   = {2007}
}

Comments

AMS-LaTeX; 47 pages, 3 tables, 2 figures comprising 3 EPS diagrams