Construction for a class of interpolation multiscaling functions with dilation factor a≥3
Computers & Mathematics with Applications
Generalized interpolating refinable function vectors
Journal of Computational and Applied Mathematics
| Hi-index | 35.68 |
Multiwavelet bases of L2 consist of families of functions {2j/2ψ2(2jx-k)}. By allowing more than one function {ψ1,ψ2}, multiwavelets provide some useful applications in signal processing and nice features such as symmetry and orthogonality. The elementary structure for multiwavelets is the multiresolution analysis of multiplicity two {Vj} generated by dilating the basic subspace V0. This subspace V0 is generated by a multiple refinable function φ=(φ1,φ2) T (refinable vector of functions) satisfying a vector refinement equation φ(x)=Σa(k)φ(2x-k). Here, each a(k) is a 2×2 matrix. In this paper, we investigate interpolatory orthogonal multiple refinable functions and multiwavelets. The interpolatory property here means that φ1 and φ2 vanish at all integers and half integers, except that φ1 (0)=1 and φ2(1/2)=1. When φ is both interpolatory and orthogonal (which is impossible for scalar refinable functions), the coefficients in the multiresolution representation can be realized by sampling instead of inner products. If f(x)=Σ{c1(k)φ1(2Nx-k)+c2 (k)φ2(2Nx-k)}, then c1(k)=f(k/2N) and c2(k)=f(k/2N +1/2N+1) for k∈Z. What is more, the orthogonal multiwavelets we construct here are also interpolatory. We show that the refinement mask for an interpolatory orthogonal multiple refinable function and multiwavelets (filterbank) is reduced to a scalar CQF. The approximation order of interpolatory multiple refinable functions is described. A complete characterization of interpolatory orthogonal multiple refinable functions is given in this paper. However, interpolatory orthogonal multiple refinable functions cannot be symmetric. Examples are presented to illustrate the general theory