English

Remez-Type Inequality for Smooth Functions

Classical Analysis and ODEs 2013-06-18 v1

Abstract

The classical Remez inequality bounds the maximum of the absolute value of a polynomial P(x)P(x) of degree dd on [1,1][-1,1] through the maximum of its absolute value on any subset ZZ of positive measure in [1,1][-1,1]. Similarly, in several variables the maximum of the absolute value of a polynomial P(x)P(x) of degree dd on the unit ball BnRnB^n \subset {\mathbb R}^n can be bounded through the maximum of its absolute value on any subset ZQ1nZ\subset Q^n_1 of positive nn-measure mn(Z)m_n(Z). In \cite{Yom} a stronger version of Remez inequality was obtained: the Lebesgue nn-measure mnm_n was replaced by a certain geometric quantity ωn,d(Z)\omega_{n,d}(Z) satisfying ωn,d(Z)mn(Z)\omega_{n,d}(Z)\geq m_n(Z) for any measurable ZZ. The quantity ωn,d(Z)\omega_{n,d}(Z) can be effectively estimated in terms of the metric entropy of ZZ and it may be nonzero for discrete and even finite sets ZZ. In the present paper we extend Remez inequality to functions of finite smoothness. This is done by combining the result of \cite{Yom} with the Taylor polynomial approximation of smooth functions. As a consequence we obtain explicit lower bounds in some examples in the Whitney problem of a CkC^k-smooth extrapolation from a given set ZZ, in terms of the geometry of ZZ.

Keywords

Cite

@article{arxiv.1306.3641,
  title  = {Remez-Type Inequality for Smooth Functions},
  author = {Yosef Yomdin},
  journal= {arXiv preprint arXiv:1306.3641},
  year   = {2013}
}
R2 v1 2026-06-22T00:34:28.004Z