English

Differentiation by integration with Jacobi polynomials

Numerical Analysis 2011-03-04 v2

Abstract

In this paper, the numerical differentiation by integration method based on Jacobi polynomials originally introduced by Mboup, Fliess and Join is revisited in the central case where the used integration window is centered. Such method based on Jacobi polynomials was introduced through an algebraic approach and extends the numerical differentiation by integration method introduced by Lanczos. The here proposed method is used to estimate the nthn^{th} (nNn \in \mathbb{N}) order derivative from noisy data of a smooth function belonging to at least Cn+1+qC^{n+1+q} (qN)(q \in \mathbb{N}). In the recent paper of Mboup, Fliess and Join, where the causal and anti-causal case were investigated, the mismodelling due to the truncation of the Taylor expansion was investigated and improved allowing a small time-delay in the derivative estimation. Here, for the central case, we show that the bias error is O(hq+2)O(h^{q+2}) where hh is the integration window length for fCn+q+2f\in C^{n+q+2} in the noise free case and the corresponding convergence rate is O(δq+1n+1+q)O(\delta^{\frac{q+1}{n+1+q}}) where δ\delta is the noise level for a well chosen integration window length. Numerical examples show that this proposed method is stable and effective.

Keywords

Cite

@article{arxiv.1012.5483,
  title  = {Differentiation by integration with Jacobi polynomials},
  author = {Da-Yan Liu and Olivier Gibaru and Wilfrid Perruquetti},
  journal= {arXiv preprint arXiv:1012.5483},
  year   = {2011}
}
R2 v1 2026-06-21T17:04:12.473Z