On a Geometric Approach to the Estimation of Interpolation Projectors

Abstract

Suppose is a closed bounded subset of Rn, S is an n-dimensional non-degenerate simplex, (;S):= \σ≥ 1: \, ⊂ σ S\. Here σ S is the result of homothety of S with respect to the center of gravity with coefficient σ. Let d≥ n+1, 1(x),…,d(x) be linearly independent monomials in n variables, 1(x) 1, 2(x)=x1,\ …, \ n+1(x)=xn. Put := lin(1,…,d). The interpolation projector P: C() with a set of nodes x(1),…, x(d) ∈ is defined by equalities Pf(x(j))=f(x(j)). Denote by \|P\| the norm of P as an operator from C() to C(). Consider the mapping T: Rn Rd-1 of the form T(x):=(2(x),…,d(x)). We have the following inequalities: 12(1+1d-1)(\|P\|-1)+1 ≤ (T();S)≤ d2(\|P\|-1)+1. Here S is the (d-1)-dimensional simplex with vertices T(x(j)). We discuss this and other relations for polynomial interpolation of functions continuous on a segment. The results of numerical analysis are presented.