English

Interpolation by Linear Functions on an $n$-Dimensional Ball

Metric Geometry 2020-02-25 v1

Abstract

By B=B(x(0);R)B=B(x^{(0)};R) we denote the Euclidean ball in Rn{\mathbb R}^n given by the inequality xx(0)R\|x-x^{(0)}\|\leq R. Here x(0)Rn,R>0x^{(0)}\in{\mathbb R}^n, R>0, x:=(i=1nxi2)1/2\|x\|:=\left(\sum_{i=1}^n x_i^2\right)^{1/2}. We mean by C(B)C(B) the space of continuous functions f:BRf:B\to{\mathbb R} with the norm fC(B):=maxxBf(x)\|f\|_{C(B)}:=\max_{x\in B}|f(x)| and by Π1(Rn)\Pi_1\left({\mathbb R}^n\right) the set of polynomials in nn variables of degree 1\leq 1, i.e., linear functions on Rn{\mathbb R}^n. Let x(1),,x(n+1)x^{(1)}, \ldots, x^{(n+1)} be the vertices of nn-dimensional nondegenerate simplex SBS\subset B. The interpolation projector P:C(B)Π1(Rn)P:C(B)\to \Pi_1({\mathbb R}^n) corresponding to SS is defined by the equalities Pf(x(j))=f(x(j)).Pf\left(x^{(j)}\right)=f\left(x^{(j)}\right). We obtain the formula to compute the norm of PP as an operator from C(B)C(B) into C(B)C(B) via x(0)x^{(0)}, RR and coefficients of basic Lagrange polynomials of SS. In more details we study the case when SS is a regular simplex inscribed into Bn=B(0,1)B_n=B(0,1).

Keywords

Cite

@article{arxiv.1905.03141,
  title  = {Interpolation by Linear Functions on an $n$-Dimensional Ball},
  author = {Mikhail Nevskii and Alexey Ukhalov},
  journal= {arXiv preprint arXiv:1905.03141},
  year   = {2020}
}

Comments

17 pages, 6 figures, 1 table

R2 v1 2026-06-23T09:00:30.662Z