HE Yuan,ZHANG Jia-ling

(School of Science,Kunming University of Science and Technology,Kunming 650500,China)

NEW RECURRENCE FORMULAE FOR THE POLYLOGARITHM FUNCTION

HE Yuan,ZHANG Jia-ling

(School of Science,Kunming University of Science and Technology,Kunming 650500,China)

In this paper,we perform a further investigation for the polylogarithm function at negative integral arguments.By applying the generating function methods and Padé approximation techniques,we establish some new recurrence formulae for this type function and present some illustrative special cases of main results.

polylogarithm function;generating function;Padé approximants;recurrence formulae

1 Introduction

Letsandzbe complex numbers,the polylogarithm function Lis(z)is de fined by means of the Dirichlet series

which is valid for arbitrary complex ordersand for all complex argumentszwith|z|＜1 and can be extended to|z|≥1 by the process of analytic continuation.

The polylogarithm function at zero and negative integral arguments are referred to as the polypseudologarithms(or polypseudologs)of ordernby Lee[8].It is worth noticing that the values of polypseudologrithms atz=1 are related to the values of the Riemann zeta functionζ(s)at negative integers and are expressed in terms of the Bernoulli numbersBn,as follows(see,e.g.,[4,8])

In[11],Truesdell gave a closed formula for the polypseudologarithms,as follows

whereS(n,k)is the familiar Stirling numbers of the second kind.In[6],Eastham showed that there is no pure recurrence relation of the form

wherenis a positive integer,r≥nis allowed.TheAn(z)are algebraic functions ofzandA0(z)is not identically zero.More recently,Cvijovi?[5]discovered some similar ones for the polypseudologarithms to formula(1.3),and also established a new type closed formula for the polypseudologarithms in the following way

where[x]denotes the greatest integer≤xandT(n,k)is the tangent numbers(of orderk)or the higher order tangent numbers given by(see,e.g.,[3])

Motivated by the work of Eastham and Cvijovi?,in this paper we perform a further investigation for the polylogarithm function at negative integral arguments,and establish some new recurrence formulae for this type function to state that there exist some explicit recurrence relations of form(1.4)for the polypseudologarithms by applying the generating function methods and Padé approximation techniques.And we accordingly consider some illustrative special cases as well as immediate consequences of the main results.

2 Padé Approximants

We begin by recalling the de finition of Padé approximation to general series and their expression in the case of the exponential function.Letm,nbe non-negative integers and letPkbe the set of all polynomials of degree≤k.Given a functionfwith a Taylor expansion

in a neighborhood of the origin,a Padé form of type(m,n)is a pair(P,Q)satisfying that

and

It is clear that every Padé form of type(m,n)forf(t)always exists and obeys the same rational function.The uniquely determined rational functionP/Qis called the Padé approximant of type(m,n)forf(t),and is denoted by[m/n]f(t)orrm,n[f;t],see for example,[1,2].

The study of Padé approximants to the exponential function was initiated by Hermite[7]and then continued by Padé[9].Given a pair(m,n)of nonnegative integers,the Padé approximant of type(m,n)foretis the unique rational function

with the property that

Unlike Padé approximants to other functions,it is possible to determine explicit formulae forPm,nandQm,n(see,e.g.,[10,p.245])

and

We here refer respectively toPm,n(t)andQm,n(t)as the Padé numerator and denominator of type(m,n)foret.In next section,we shall use the above Padé approximation to the exponential function to establish some new recurrence formulae for the polylogarithm function at zero and negative integral arguments.

3 The Restatements of Results

In[4],Cvijovi? discovered some similar formulae to(1.3)by making use of the following generating functions for the polypseudologarithms(see,e.g.,[11,12])

and

We shall replace the exponential functionetnot by its Taylor expansion aroundt=0 but by its Padé approximant in the generating function of the polypseudologarithms.We first rewrite the first formula of(3.1)as follows

If we denote the right hand side of(2.8)bySm,n(t),the Padé approximant for the exponential functionetcan be expressed as

We now apply(3.4)to(3.3)and then obtain

If we apply the exponential seriesin the right hand side of(2.8),with the help of the familiar beta function,we get

For convenience,we considerpm,n;k,qm,n;kandsm,n;kof the coefficients of the polynomialsPm,n(t),Qm,n(t)andSm,n(t)such that

Obviously,the coefficientspm,n;k,qm,n;kandsm,n;kobey

and

respectively.If we apply(3.7)to(3.5),we obtain

from which and the familiar Cauchy product,we discover

Comparing the coefficients oftlin(3.11)gives that for 1≤l≤m+n,

which together with(3.8)yields the following result.

Theorem 3.1Letl,m,nbe non-negative integers.Then for positive integerlwith max(m,n)＜l≤m+n,

We next discuss some special cases of Theorem 3.1.Settingl=m+nin Theorem 3.1,we obtain that for positive integersm,n,

It is obvious that the casem=1 in(3.14)gives that for positive integern,

and the casen=1 in(3.14)arises

If we compare the coefficients oftlin(3.11)forl≥m+n+1,then

Hence applying(3.8)and(3.9)to(3.17)gives the following result.

Theorem 3.2Letm,nbe non-negative integers.Then for positive integerlwithl≥m+n+1,

It follows that we show some special cases of Theorem 3.2.Takingl=m+n+1 in Theorem 3.2,we obtain that for non-negative integersm,n,

In particular,the casem=0 in(3.19)arises

More generally,by settingm=0 andl=n+rin Theorem 3.2,we get that for non-negative integernand positive integerr,

And the casen=0 in(3.21)yields another recurrence formula to compute the values of the polypseudologarithms with Li0(z)=z/(1?z):

It becomes obvious that formulae(3.15),(3.16)and(3.22)mean that there exists pure recurrence relations of form(1.4)for the polypseudologarithms,respectively.

AcknowledgementThis work was done during the authors’visit for Department of Computer Science,State University of New York at Stony Brook.

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關(guān)于polylogarithm函數(shù)新的循環(huán)公式

何 圓,張家玲
(昆明理工大學(xué)理學(xué)院,云南昆明 650500)

本文對polylogarithm函數(shù)在負整數(shù)點的情形作了進一步的研究.利用生成函數(shù)方法及Padé估計技巧,建立了此類函數(shù)的一些新的循環(huán)公式,并給出了主要結(jié)果的一些特殊情況.

polylogarithm函數(shù);生成函數(shù);Padé估計;循環(huán)公式

O156.4

11E41;33E20;05A19

A

0255-7797(2017)06-1154-07

date:2015-01-09Accepted date:2015-10-10

Supported by the Foundation for Fostering Talents in Kunming University of Science and Technology(KKSY201307047)and the National Natural Science Foundation of China(11326050;11071194).

Biography:He Yuan(1982–),male,born at Neijiang,Sichuan,associate professor,major in number theory and its applications.