广义中心阶乘数与高阶Nrlund Euler-Bernoulli多项式

本文讨论了广义中心阶乘数的性质,刻画了广义中心阶乘数与高阶Ｅｕｌｅｒ－Ｂｅｒｎｏｕｌｌｉ数和多项式的关系,建立了一些包含 Ｎｏｒｌｕｎｄ Ｅｕｌｅｒ－Ｂｅｒｎｏｕｌｌｉ多项式恒等式,推广了 Ｄｉｌｃｈｅｒ Ｋ．［１］,Ｚｈａｎｇ Ｗｅｎｐｅｎｇ［２］和 Ｚｅｉｔｌｉｎ　Ｄａｖｉｄ［３］的结果．     

高阶多元Euler多项式和高阶多元Bernoulli多项式

本文给出了高阶多元Ｅｕｌｅｒ数和多项式与高阶多元Ｂｅｒｎｏｕｌｉ数和多项式的定义，讨论了它们的一些重要性质，得到了高阶多元Ｅｕｌｅｒ多项式（数）和高阶多元Ｂｅｒｎｏｕｌｉ多项式（数）的关系式·     

n元Euler数和多项式与n元Bernoulli数和多项式

本文给出了ｎ元Ｅｕｌｅｒ数，ｎ元Ｂｅｒｎｏｕｌｌｉ数，ｎ元Ｅｕｌｅｒ多项式，ｎ元Ｂｅｒｎｏｕｌｌｉ多项式的定义，导出了它们的母函数，得到了ｎ元Ｅｕｌｅｒ数与Ｅｕｌｅｒ数ｎ元Ｂｅｒｎｏｕｌｌｉ数与Ｂｅｒｎｏｕｌｌｉ数，ｎ元Ｅｕｌｅｒ多项式与Ｂｅｒｎｏｕｌｌｉ多项式的关系式。     

高阶多元Euler多项多和高阶多元Bernoulli多项式

本给出了高阶多元Ｅｕｌｅｒ数和多项式与同阶多元Ｂｅｒｎｏｕｌｌｉ数和多项式的定义，讨论了它们的一些重要性质，得到了高阶多元Ｅｕｌｅｒ多项式（数）和高阶多元Ｂｅｒｎｏｕｌｌｉ多项式（数）的关系式。     

关于高阶Euler多项式的一点注记

对任何复数ｘ，考虑幂级数展开式：（２ｅｔ＋１）ｋｅｘｔ＝∑ｎ≥０Ｅ（ｋ）ｎ（ｘ）ｔｎｎ！｜ｔ｜＜π，则函数Ｅ（ｋ）ｎ（ｘ）称为ｋ阶Ｅｕｌｅｒ多项式［１］．特别地，Ｅ（１）ｎ（ｘ）＝Ｅｎ（ｘ）为普通Ｅｕｌｅｒ多项式；Ｅｎ＝２ｎＥｎ（１２）为Ｅｕ－ｌｅｒ...     

涉及Euler数,Bernoulli数和推广的第一类Stirling数…

利用递推关系把文［１］、［２］中的有关结论推广到一般情形，建立起涉及Ｅｕｌｅｒ数、Ｂｅｒｎｏｕｌｌｉ数和推广的第一类Ｓｔｉｒｌｉｎｇ数的一些恒等式。     

广义n阶Euler-Bernoulli多项式

本文得到了广义n阶Euler数和广义n阶Bernoulli数,广义n阶Euler多项式和广义n阶Bernoulli多项式的关系式。     

高阶多元Norlund Euler-Bernoulli多项式

给出了高阶多元Nrlund Euler多项式和高阶多元Nrlund Bernoulli多项式的定义,讨论了它们的一些重要性质,建立了一些包含递归序列和上述多项式的恒等式.     

联系Euler数和Bernoulli数的一些恒等式

本文的主要目的是建立一些包含Ｅｕｌｅｒ和数和Ｂｅｒｎｏｕｌｌｉ数的函数方程，进而给出了联系Ｅｕｌｅｒ数和Ｂｅｒｎｏｕｌｌｉ数的几个恒等式和同余式。     

高阶退化Bernoulli数和多项式

本文研究了高阶退化Berrioulli数和多项式的两个显明公式，得到了一个包含高阶Bemoulli数和Stirling数的恒等式，并推广了F．H．Howard，S．Shirai和K．I．Sato的结果。     

Degenerate Bernoulli polynomials, generalized factorial sums, and their applications

We prove a general symmetric identity involving the degenerate Bernoulli polynomials and sums of generalized falling factorials, which unifies several known identities for Bernoulli and degenerate Bernoulli numbers and polynomials. We use this identity to describe some combinatorial relations between these polynomials and generalized factorial sums. As further applications we derive several identities, recurrences, and congruences involving the Bernoulli numbers, degenerate Bernoulli numbers, generalized factorial sums, Stirling numbers of the first kind, Bernoulli numbers of higher order, and Bernoulli numbers of the second kind.     

Connections between central factorial numbers and Bernoulli polynomials

In the paper, the author presents two finite discrete convolutions that combines central factorial numbers of both kinds and Bernoulli polynomials.     

A simple method to find out when an ordinary differential equation is separable

In many statistical discussions, especially in data analysis, the idea of polynomials plays a key role. For example, Dwyer [1] employed polynomials to express factorial moments of discrete distribution in terms of cumulative totals. Traditionally, polynomials are derived using the difference operator method (see [2], p. 134]). In this article, using the differential equation approach as an alternative method, we obtain generalized exponential and logarithmic polynomials, and find their special cases appearing in statistical signal‐noise models.     

Computation methods for combinatorial sums and Euler‐type numbers related to new families of numbers

The aim of this article is to define some new families of the special numbers. These numbers provide some further motivation for computation of combinatorial sums involving binomial coefficients and the Euler kind numbers of negative order. We can show that these numbers are related to the well‐known numbers and polynomials such as the Stirling numbers of the second kind and the central factorial numbers, the array polynomials, the rook numbers and polynomials, the Bernstein basis functions and others. In order to derive our new identities and relations for these numbers, we use a technique including the generating functions and functional equations. Finally, we give not only a computational algorithm for these numbers but also some numerical values of these numbers and the Euler numbers of negative order with tables. We also give some combinatorial interpretations of our new numbers. Copyright © 2016 John Wiley & Sons, Ltd.     

Reciprocal relations of Bernoulli and Euler numbers/polynomials

By means of the symmetric summation theorem on polynomial differences due to Chu and Magli [Summation formulae on reciprocal sequences. European J Combin. 2007;28(3):921–930], we examine Bernoulli and Euler polynomials of higher order. Several reciprocal relations on Bernoulli and Euler numbers and polynomials are established, including some recent ones obtained by Agoh Shortened recurrence relations for generalized Bernoulli numbers and polynomials. J Number Theory. 2017;176:149–173.     

A Unified Approach to Generalized Stirling Functions

Here presented is a unified approach to generalized Stirling functions by using generalized factorial functions, k-Gamma functions, generalized divided difference, and the unified expression of Stirling numbers defined in [16]. Previous well-known Stirling functions introduced by Butzer and Hauss [4], Butzer, Kilbas, and Trujilloet [6] and others are included as particular cases of our generalization. Some basic properties related to our general pattern such as their recursive relations, generating functions, and asymptotic properties are discussed,which extend the corresponding results about the Stirling numbers shown in [21] to the defined Stirling functions.     

Peters type polynomials and numbers and their generating functions: Approach with p‐adic integral method

The aim of this paper is to introduce and investigate some of the primary generalizations and unifications of the Peters polynomials and numbers by means of convenient generating functions and p‐adic integrals method. Various fundamental properties of these polynomials and numbers involving some explicit series and integral representations in terms of the generalized Stirling numbers, generalized harmonic sums, and some well‐known special numbers and polynomials are presented. By using p‐adic integrals, we construct generating functions for Peters type polynomials and numbers (Apostol‐type Peters numbers and polynomials). By using these functions with their partial derivative eqautions and functional equations, we derive many properties, relations, explicit formulas, and identities including the Apostol‐Bernoulli polynomials, the Apostol‐Euler polynomials, the Boole polynomials, the Bernoulli polynomials, and numbers of the second kind, generalized harmonic sums. A brief revealing and historical information for the Peters type polynomials are given. Some of the formulas given in this article are given critiques and comments between previously well‐known formulas. Finally, two open problems for interpolation functions for Apostol‐type Peters numbers and polynomials are revealed.     

Generalized Bernoulli Polynomials and Numbers,Revisited

We describe with some new details the connection between generalized Bernoulli polynomials, Bernoulli polynomials and generalized Bernoulli numbers (Norlund polynomials). A new recursive and explicit formulae for these polynomials are derived.