English

Approximation by amplitude and frequency operators

Classical Analysis and ODEs 2016-03-08 v3

Abstract

We study Pad\'{e} interpolation at the node z=0z=0 of functions f(z)=m=0fmzmf(z)=\sum_{m=0}^{\infty} f_m z^m, analytic in a neighbourhood of this node, by amplitude and frequency operators (sums) of the form k=1nμkh(λkz),μk,λkC. \sum_{k=1}^n \mu_k h(\lambda_k z), \qquad \mu_k,\lambda_k\in \mathbb{C}. Here h(z)=m=0hmzmh(z)=\sum_{m=0}^{\infty} h_m z^m, hm0h_m\ne 0, is a fixed (basis) function, analytic at the origin, and the interpolation is carried out by an appropriate choice of amplitudes μk\mu_k and frequencies λk\lambda_k. The solvability of the 2n2n-multiple interpolation problem is determined by the solvability of the associated moment problem k=1nμkλkm=fm/hm,m=0,2n1. \sum_{k=1}^n\mu_k \lambda_k^m={f_m}/{h_m}, \qquad m=\overline{0,2n-1}. In a number of cases, when the moment problem is consistent, it can be solved by the classical method due to Prony and Sylvester, moreover, one can easily construct the corresponding interpolating sum too. In the case of inconsistent moment problems, we propose a regularization method, which consists in adding a special binomial c1zn1+c2z2n1c_1z^{n-1}+c_2 z^{2n-1} to an amplitude and frequency sum so that the moment problem, associated with the sum obtained, can be already solved by the method of Prony and Sylvester. This approach enables us to obtain interpolation formulas with nn nodes λkz\lambda_k z, being exact for the polynomials of degree 2n1\le 2n-1, whilst traditional formulas with the same number of nodes are usually exact only for the polynomials of degree n1\le n-1. The regularization method is applied to numerical differentiation and extrapolation.

Keywords

Cite

@article{arxiv.1409.4188,
  title  = {Approximation by amplitude and frequency operators},
  author = {Petr Chunaev and Vladimir Danchenko},
  journal= {arXiv preprint arXiv:1409.4188},
  year   = {2016}
}

Comments

We added several examples and remarks recommended by the referees and also corrected minor misprints found in the previous versions

R2 v1 2026-06-22T05:56:38.648Z