APPROXIMATIVE PROPERTIES OF ABEL–POISSON-TYPE OPERATORS ON THE GENERALIZED HÖLDER CLASSES

Q3 Engineering

Journal of Automation and Information Sciences Pub Date : 2021-01-01 DOI:10.34229/0572-2691-2021-1-6

Yu. I. Kharkevich, A. Khanin

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引用次数: 1

Abstract

The paper deals with topical issues of the modern applied mathematics, in particular, an investigation of approximative properties of Abel–Poisson-type operators on the so-called generalized Hölder’s function classes. It is known, that by the generalized Hölder’s function classes we mean the classes of continuous -periodic functions determined by a first-order modulus of continuity. The notion of the modulus of continuity, in turn, was formulated in the papers of famous French mathematician Lebesgue in the beginning of the last century, and since then it belongs to the most important characteristics of smoothness for continuous functions, which can describe all natural processes in mathematical modeling. At the same time, the Abel-Poisson-type operators themselves are the solutions of elliptic-type partial differential equations. That is why the results obtained in this paper are significant for subsequent research in the field of applied mathematics. The theorem proved in this paper characterizes the upper bound of deviation of continuous -periodic functions determined by a first-order modulus of continuity from their Abel–Poisson-type operators. Hence, the classical Kolmogorov–Nikol’skii problem in A.I. Stepanets sense is solved on the approximation of functions from the classes by their Abel–Poisson-type operators. We know, that the Abel–Poisson-type operators, in partial cases, turn to the well-known in applied mathematics Poisson and Jacobi–Weierstrass operators. Therefore, from the obtained theorem follow the asymptotic equalities for the upper bounds of deviation of functions from the Hölder’s classes of order from their Poisson and Jacobi–Weierstrass operators, respectively. The obtained equalities generalize the known in this direction results from the field of applied mathematics.

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广义HÖLDER类上ABEL–POISSON型算子的逼近性质

本文讨论了现代应用数学的热点问题，特别是研究了Abel–Poisson型算子在所谓的广义Hölder函数类上的近似性质。众所周知，广义Hölder函数类是指由一阶连续模确定的连续周期函数类。连续模的概念反过来在上世纪初法国著名数学家勒贝格的论文中提出，从那时起，它属于连续函数光滑性的最重要特征，可以描述数学建模中的所有自然过程。同时，Abel-Poisson型算子本身就是椭圆型偏微分方程的解。这就是为什么本文的结果对应用数学领域的后续研究具有重要意义。本文证明的定理刻画了由Abel–Poisson型算子的一阶连续模确定的连续周期函数的偏差上界。因此，A.I.Stepanets意义上的经典Kolmogorov–Nikol’skii问题是通过Abel–Poisson型算子在类函数的近似上求解的。我们知道，Abel–Poisson型算子，在部分情况下，转向应用数学中众所周知的Poisson和Jacobi–Weierstrass算子。因此，根据所获得的定理，分别从泊松算子和Jacobi–Weierstrass算子得到Hölder阶类函数偏差上界的渐近等式。所得到的等式推广了应用数学领域在这个方向上已知的结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Automation and Information Sciences AUTOMATION & CONTROL SYSTEMS-

自引率

0.00%

发文量

审稿时长

6-12 weeks

期刊介绍： This journal contains translations of papers from the Russian-language bimonthly "Mezhdunarodnyi nauchno-tekhnicheskiy zhurnal "Problemy upravleniya i informatiki". Subjects covered include information sciences such as pattern recognition, forecasting, identification and evaluation of complex systems, information security, fault diagnosis and reliability. In addition, the journal also deals with such automation subjects as adaptive, stochastic and optimal control, control and identification under uncertainty, robotics, and applications of user-friendly computers in management of economic, industrial, biological, and medical systems. The Journal of Automation and Information Sciences will appeal to professionals in control systems, communications, computers, engineering in biology and medicine, instrumentation and measurement, and those interested in the social implications of technology.