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Discrete least squares approximation of piecewise-linear functions by trigonometric polynomials
G. G. Akniyev Dagestan scientific center of RAS,
45, Gadzhieva st., Makhachkala 367025, Russia
Аннотация:
Let
$N$ be a natural number greater than
$1$.
Select
$N$ uniformly distributed points
$t_k = 2\pi k / N$ $(0 \leq k
\leq N - 1)$ on
$[0,2\pi]$.
Denote by
$L_{n,N}(f)=L_{n,N}(f,x)$ $(1\leq n\leq N/2)$ the
trigonometric polynomial of order
$n$ possessing the least quadratic deviation
from
$f$ with respect to the system
$\{t_k\}_{k=0}^{N-1}$.
In this article approximation of functions by the polynomials
$L_{n,N}(f,x)$ is
considered.
Special attention is paid to approximation of
$2\pi$-periodic functions
$f_1$ and
$f_2$ by the polynomials
$L_{n,N}(f,x)$,
where
$f_1(x)=|x|$ and
$f_2(x)=\mathrm{sign}\, x$ for
$x \in
[-\pi,\pi]$.
For the first function
$f_1$ we show that instead of the estimation
$\left|f_{1}(x)-L_{n,N}(f_{1},x)\right| \leq c\ln n/n$ which follows from the
well-known Lebesgue inequality for the polynomials
$L_{n,N}(f,x)$ we found an
exact order estimation
$\left|f_{1}(x)-L_{n,N}(f_{1},x)\right| \leq c/n$ (
$x
\in
\mathbb{R}$) which is uniform with respect to
$1 \leq n \leq N/2$.
Moreover, we found a local estimation $\left|f_{1}(x)-L_{n,N}(f_{1},x)\right|
\leq c(\varepsilon)/n^2$ (
$\left|x - \pi k\right| \geq \varepsilon$) which is
also uniform with respect to
$1 \leq n \leq N/2$.
For the second function
$f_2$ we found only a local estimation
$\left|f_{2}(x)-L_{n,N}(f_{2},x)\right| \leq c(\varepsilon)/n$ (
$\left|x - \pi
k\right| \geq \varepsilon$) which is uniform with respect to
$1 \leq n \leq
N/2$.
The proofs of these estimations are based on comparing of approximating
properties of discrete and continuous finite Fourier series.
Ключевые слова:
function approximation, trigonometric polynomials, Fourier series.
УДК:
517.521.2
MSC: 41A25 Поступила в редакцию: 11.10.2017
Исправленный вариант: 13.12.2017
Принята в печать: 15.12.2017
Язык публикации: английский
DOI:
10.15393/j3.art.2017.4070