English

Improved effective {\L}ojasiewicz inequality and applications

Algebraic Geometry 2024-12-11 v2 Logic Optimization and Control

Abstract

Let R\mathrm{R} be a real closed field. Given a closed and bounded semi-algebraic set ARnA \subset \mathrm{R}^n and semi-algebraic continuous functions f,g:ARf,g:A \rightarrow \mathrm{R}, such that f1(0)g1(0)f^{-1}(0) \subset g^{-1}(0), there exist NN and cRc \in \mathrm{R}, such that the inequality ({\L}ojasiewicz inequality) g(x)Ncf(x)|g(x)|^N \le c \cdot |f(x)| holds for all xAx \in A. In this paper we consider the case when AA is defined by a quantifier-free formula with atoms of the form P=0,P>0,PPP = 0, P >0, P \in \mathcal{P} for some finite subset of polynomials PR[X1,,Xn]d\mathcal{P} \subset \mathrm{R}[X_1,\ldots,X_n]_{\leq d}, and the graphs of f,gf,g are also defined by quantifier-free formulas with atoms of the form Q=0,Q>0,QQQ = 0, Q >0, Q \in \mathcal{Q}, for some finite set QR[X1,,Xn,Y]d\mathcal{Q} \subset \mathrm{R}[X_1,\ldots,X_n,Y]_{\leq d}. We prove that the {\L}ojasiewicz exponent NN in this case is bounded by (8d)2(n+7)(8 d)^{2(n+7)}. Our bound depends on dd and nn, but is independent of the combinatorial parameters, namely the cardinalities of P\mathcal{P} and Q\mathcal{Q}. As a consequence we improve the current best error bounds for polynomial systems under some conditions. Finally, as an abstraction of the notion of independence of the {\L}ojasiewicz exponent from the combinatorial parameters occurring in the descriptions of the given pair of functions, we prove a version of {\L}ojasiewicz inequality in polynomially bounded o-minimal structures. We prove the existence of a common {\L}ojasiewicz exponent for certain combinatorially defined infinite (but not necessarily definable) families of pairs of functions.

Keywords

Cite

@article{arxiv.2211.10034,
  title  = {Improved effective {\L}ojasiewicz inequality and applications},
  author = {Saugata Basu and Ali Mohammad-Nezhad},
  journal= {arXiv preprint arXiv:2211.10034},
  year   = {2024}
}

Comments

29 pages. Theorem 1 expanded to include a bound on the constant $c$ in the integer case. Comments welcome

R2 v1 2026-06-28T06:11:00.883Z