Order of uniform approximation by polynomial interpolation in the complex plane and beyond

Abstract

For Lagrange polynomial interpolation on open arcs X=γ in C, it is well-known that the Lebesgue constant for the family of Chebyshev points xn:=\xn,j\nj=0 on [-1,1]⊂ R has growth order of O(log(n)). The same growth order was shown in [45] for the Lebesgue constant of the family z**n:=\zn,j**\nj=0 of some properly adjusted Fej\'er points on a rectifiable smooth open arc γ⊂ C. On the other hand, in our recent work [15], it was observed that if the smooth open arc γ is replaced by an L-shape arc γ0 ⊂ C consisting of two line segments, numerical experiments suggest that the Marcinkiewicz-Zygmund inequalities are no longer valid for the family of Fej\'er points zn*:=\zn,j*\nj=0 on γ, and that the rate of growth for the corresponding Lebesgue constant L z*n is as fast as c\,log2(n) for some constant c>0. The main objective of the present paper is 3-fold: firstly, it will be shown that for the special case of the L-shape arc γ0 consisting of two line segments of the same length that meet at the angle of π/2, the growth rate of the Lebesgue constant L zn* is at least as fast as O(Log2(n)), with L zn*log2(n) = ∞; secondly, the corresponding (modified) Marcinkiewicz-Zygmund inequalities fail to hold; and thirdly, a proper adjustment zn**:=\zn,j**\nj=0 of the Fej\'er points on γ will be described to assure the growth rate of L zn** to be exactly O(Log2(n)).