On convergence of discrete methods of least squares on equidistant nodes

Abstract

We consider the well-known method of least squares on an equidistant grid with N+1 nodes on the interval [-1,1] with the goal to approximate a function f∈C[-1,1] by a polynomial of degree n. We investigate the following problem: For which ratio N/n and which functions do we have uniform convergence of the least square operator LSnN:C[-1,1]→Pn? We investigate this problem with a discrete weighting of the Jacobi-type. Thereby we describe the least square operator LSnN by the expansion of a function by Hahn polynomials Qk(·;α,β,N). Without additional assumptions to functions f∈C[-1,1] it can not be guaranteed uniform convergence. But with α=β and additional assumptions to f and (Nn)n∈N we obtain convergence and prove the following results: For an α≥0 let f∈\g∈C∞[-1,1]:\ n∞x∈[-1,1] g(n)(x)nα+1/22nn!=0\ and let (Nn)n be a sequence of natural numbers with Nn≥2n(n+1). Then the method of least squares LSnNn[f] converges uniform on [-1,1]. Before we determine the maximum error ("worst case") with respect to the sup norm on the classes Kn+1:=\f∈Cn+1[-1,1]:\ x∈[-1,1] f(n+1)(x)≤1\.