Clifford分析中的广义伯努利数与多项式

Journal of Siberian Federal University. Mathematics and Physics Pub Date : 2018-05-01 DOI:10.17516/1997-1397-2018-11-2-127-136

S. Chandragiri, O. A. Shishkina, Шрилата Чандрагири, Ольга А. Шишкина

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引用次数: 1

摘要

自然值的伯努利多项式最早是由伯努利(1713)在考虑连续自然数的幂和问题时提出的。L.欧拉研究了任意参数值的这种多项式，J. L. raabe(1851)引入了“伯努利多项式”一词。伯努利数和多项式在纯数学和应用数学领域得到了很好的研究和应用。伯努利数和多项式的各种推广变体可以在[5-11]中找到。[12]中考虑了对几个变量的一般化;本文给出了与有理格锥相关的伯努利数和多项式的定义，并证明了它们基本性质的多维类似。本文将这些结果推广到超复变量的情况。超复函数理论中的Clifford代数最早是由R. Fueter[1]在上世纪初提出的。关于这一主题的系统研究可以在[2-4]中找到。此外，还应注意进一步推进Clifford分析的论文[15-18]。在这个框架下，伯努利数和多项式的概念在[13,14]中被给出和研究。在本文中，我们给出了比文献[13,14]中更一般的伯努利多项式的概念，即，根据文献[12]的精神，我们定义了与整数矩阵相关的超复变量中的多项式。在论文的第二部分，我们给出并证明了这类多项式的基本性质。* sreelathachandragiri124@gmail.com†olga_a_sh@mail.ru c⃝西伯利亚联邦大学。版权所有

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Generalized Bernoulli Numbers and Polynomials in the Context of the Clifford Analysis

The Bernoulli polynomials for natural values of the argument were first considered by J.Bernoulli (1713) in relation to the problem of summation of powers of consecutive natural numbers. L. Euler studied such polynomials for arbitrary values of the argument, the term "Bernoulli polynomials" was introduced by J. L.Raabe (1851). The Bernoulli numbers and polynomials are well studied and find applications in fields of pure and applied mathematics. Various variants of generalization of the Bernoulli numbers and polynomials can be found in [5–11]. A generalization to several variables has been considered in [12]; in this paper definitions of the Bernoulli numbers and polynomials associated with rational lattice cones were given and multidimensional analogs of their basic properties were proved. This paper is devoted to generalization of these results to the case of hypercomplex variables. The Clifford algebra in hypercomplex function theory (HFT) was first used by R. Fueter [1] in the beginning of the last century. A systematic study of this topic can be found in [2–4]. Also, the papers [15–18] with further advancement of the Clifford analysis should be noted. The notion of the Bernoulli numbers and polynomials in this framework were given and studied in [13, 14]. In this paper we give a more genral notion of Bernoulli polynomials than in [13, 14], namely, in the spirit of [12] we define polynomials in hypercomplex variables associated with a matrix of integers. In the second section of the paper we formulate and prove basic properties of such polynomials. ∗sreelathachandragiri124@gmail.com †olga_a_sh@mail.ru c ⃝ Siberian Federal University. All rights reserved

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Journal of Siberian Federal University. Mathematics and Physics

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