Vladimir Yu. Protasov, Rinat Kamalov
Published 2024-03-24Version 1
We address the problem of the best uniform approximation of a continuous function on a convex domain. The approximation is by linear combinations of a finite system of functions (not necessarily Chebyshev) under arbitrary linear constraints. By modifying the concept of alternance and of the Remez iterative procedure we present a method, which demonstrates its efficiency in numerical problems. The linear rate of convergence is proved under some favourable assumptions. A special attention is paid to systems of complex exponents, Gaussian functions, lacunar algebraic and trigonometric polynomials. Applications to signal processing, linear ODE, switching dynamical systems, and to Markov-Bernstein type inequalities are considered.
Polynomial of best uniform approximation to $x^{-1}$ and smoothing in two-level methods
Algorithms for Solving High Dimensional PDEs: From Nonlinear Monte Carlo to Machine Learning
High-order quasi-Helmholtz Projectors: Definition, Analyses, Algorithms
![QR code for arXiv:2403.16330 [math.NA]](http://oss.arxitics.com/images/favicon.svg)