English

Smoothing of weights in the Bernstein approximation problem

Functional Analysis 2017-04-28 v2

Abstract

In 1924 S.Bernstein asked for conditions on a uniformly bounded on R\mathbb{R} Borel function (weight) w:R[0,+)w: \mathbb{R} \to [0, +\infty ) which imply the denseness of algebraic polynomials P{\mathcal{P} } in the seminormed space Cw0 C^{0}_{w} defined as the linear set {fC(R)  w(x)f(x)0 \mboxas x+} \{f \in C (\mathbb{R}) \ | \ w (x) f (x) \to 0 \ \mbox{as} \ {|x| \to +\infty}\} equipped with the seminorm fw:=supxRw(x)f(x)\|f\|_{w} := \sup_{x \in {\mathbb{R}}} w(x)| f( x )|. In 1998 A.Borichev and M.Sodin completely solved this problem for all those weights ww for which P{\mathcal{P} } is dense in Cw0 C^{0}_{w} but there exists a positive integer n=n(w)n=n(w) such that P\mathcal{P} is not dense in C(1+x2)nw0 C^{0}_{(1+x^{2})^{n} w}. In the present paper we establish that if P\mathcal{P} is dense in C(1+x2)nw0 C^{0}_{(1+x^{2})^{n} w} for all n0n \geq 0 then for arbitrary ε>0\varepsilon > 0 there exists a weight WεC(R)W_{\varepsilon} \in C^{\infty} (\mathbb{R}) such that P{\mathcal{P}} is dense in C(1+x2)nWε0C^{\,0}_{(1+x^{2})^{n} W_{\varepsilon}} for every n0n \geq 0 and Wε(x)w(x)+eεxW_{\varepsilon} (x) \geq w (x) + \mathrm{e}^{- \varepsilon |x|} for all xRx\in \mathbb{R}.

Keywords

Cite

@article{arxiv.1611.06708,
  title  = {Smoothing of weights in the Bernstein approximation problem},
  author = {Andrew Bakan and Jürgen Prestin},
  journal= {arXiv preprint arXiv:1611.06708},
  year   = {2017}
}

Comments

15 pages

R2 v1 2026-06-22T16:58:57.258Z