English

Sampling for approximating $R$-limited functions

Information Theory 2017-09-08 v1 math.IT

Abstract

RR-limited functions are multivariate generalization of band-limited functions whose Fourier transforms are supported within a compact region RRnR\subset\mathbb{R}^{n}. In this work, we generalize sampling and interpolation theorems for band-limited functions to RR-limited functions. More precisely, we investigated the following question: "For a function compactly supported within a region similar to RR, does there exist an RR-limited function that agrees with the function over its support for a desired accuracy?". Starting with the Fourier domain definition of an RR-limited function, we write the equivalent convolution and a discrete Fourier transform representations for RR-limited functions through approximation of the convolution kernel using a discrete subset of Fourier basis. The accuracy of the approximation of the convolution kernel determines the accuracy of the discrete Fourier representation. Construction of the discretization can be achieved using the tools from approximation theory as demonstrated in the appendices. The main contribution of this work is proving the equivalence between the discretization of the Fourier and convolution representations of RR-limited functions. Here discrete convolution representation is restricted to shifts over a compactly supported region similar to RR. We show that discrete shifts for the convolution representation are equivalent to the spectral parameters used in discretization of the Fourier representation of the convolution kernel. This result is a generalization of the cardinal theorem of interpolation of band-limited functions. The error corresponding to discrete convolution representation is also bounded by the approximation of the convolution kernel using discretized Fourier basis.

Keywords

Cite

@article{arxiv.1709.02086,
  title  = {Sampling for approximating $R$-limited functions},
  author = {Can Evren Yarman},
  journal= {arXiv preprint arXiv:1709.02086},
  year   = {2017}
}
R2 v1 2026-06-22T21:35:32.463Z