Barnes-type Peters polynomial with umbral calculus viewpoint

In this paper, we consider the Barnes-type Peters polynomials. We present several explicit formulas and recurrence relations for these polynomials. Also, we establish a connection between our polynomials and several known families of polynomials.

MSC:05A40, 11B83.

The aim of this paper is to use umbral calculus to obtain several new and interesting identities of Barnes-type Peters polynomials. Umbral calculus has been used in numerous problems of mathematics (for example, see [1–10]). Umbral techniques have been used in different areas of physics; for example, it was used in group theory and quantum mechanics by Biedenharn et al. [11, 12] (for other examples, see [3, 10, 13–18]).

Let $r\in {\mathbb{Z}}_{>0}$. Here we will consider the polynomials $S_n(x)=S_n(x|{\lambda }_1,\dots ,{\lambda }_r;{\mu }_1,\dots ,{\mu }_r)$ and ${\hat{S}}_n(x)={\hat{S}}_n(x|{\lambda }_1,\dots ,{\lambda }_r;{\mu }_1,\dots ,{\mu }_r)$, which are called Barnes-type Peters polynomials of the first kind and of the second kind, respectively, and are given by

where ${\lambda }_1,\dots ,{\lambda }_r,{\mu }_1,\dots ,{\mu }_r\in \mathbb{C}$ with ${\lambda }_1,\dots ,{\lambda }_r\ne 0$. If $r=1$, then these polynomials are generalizations of Boole polynomials, see [19]. If ${\mu }_1=\cdots ={\mu }_r=1$, then $S_n(x|\mathit{\lambda })=S_n(x|{\lambda }_1,\dots ,{\lambda }_r)=S_n(x|{\lambda }_1,\dots ,{\lambda }_r;1,\dots ,1)$ and ${\hat{S}}_n(x|\mathit{\lambda })={\hat{S}}_n(x|{\lambda }_1,\dots ,{\lambda }_r)={\hat{S}}_n(x|{\lambda }_1,\dots ,{\lambda }_r;1,\dots ,1)$ are called Barnes-type Boole polynomials of the first kind and of the second kind. So,

We introduce the polynomials $E_n(x|\mathit{\lambda };\mathit{\mu })=E_n(x|{\lambda }_1,\dots ,{\lambda }_r;{\mu }_1,\dots ,{\mu }_r)$ with the generating function

These polynomials may be called generalized Barnes-type Euler polynomials. When ${\mu }_1=\cdots ={\mu }_r=1$, $E_n(x|\mathit{\lambda })=E_n(x|{\lambda }_1,\dots ,{\lambda }_r)=E_n(x|{\lambda }_1,\dots ,{\lambda }_r;1,\dots ,1)$ are called the Barnes-type Euler polynomials. If further ${\lambda }_1=\cdots ={\lambda }_r=1$, $E_n^{(r)}(x)=E_n(x|1,\dots ,1;1,\dots ,1)$ are called the Euler polynomials of order r. When $x=0$, $S_n=S_n(\mathit{\lambda };\mathit{\mu })=S_n(0|\mathit{\lambda };\mathit{\mu })$ and ${\hat{S}}_n={\hat{S}}_n(\mathit{\lambda };\mathit{\mu })={\hat{S}}_n(0|\mathit{\lambda };\mathit{\mu })$ are called Barnes-type Peters numbers of the first kind and of the second kind, respectively.

Let Π be the algebra of polynomials in a single variable x over ℂ, and let ${\mathrm{\Pi }}^{\ast }$ be the vector space of all linear functionals on Π. We denote the action of a linear functional L on a polynomial $p(x)$ by $〈L|p(x)〉$, and we define the vector space structure on ${\mathrm{\Pi }}^{\ast }$ by

where $c,c^{\prime }\in \mathbb{C}$ (see [19–22]). We define the algebra of formal power series in a single variable t to be

The formal power series in the variable t defines a linear functional on Π by setting

By (1.3) and (1.4), we have

where ${\delta }_{n,k}$ is the Kronecker symbol.

Let $f_L(t)={\sum }_{n\ge 0}〈L|x^n〉\frac{t^n}{n!}$. From (1.5), we have $〈f_L(t)|x^n〉=〈L|x^n〉$. Thus, the map $L\mapsto f_L(t)$ is a vector space isomorphism from ${\mathrm{\Pi }}^{\ast }$ onto ℋ. Therefore, ℋ is thought of as a set of both formal power series and linear functionals. We call ℋ umbral algebra. Umbral calculus is the study of umbral algebra.

The order $O(f(t))$ of the non-zero power series $f(t)$ is the smallest integer k for which the coefficient of $t^k$ does not vanish (see [19–22]). If $O(f(t))=1$ (respectively, $O(f(t))=0$), then $f(t)$ is called a delta (respectively, an invertible) series. Suppose that $O(f(t))=1$ and $O(g(t))=0$, then there exists a unique sequence $s_n(x)$ of polynomials such that $〈g(t){(f(t))}^k|s_n(x)〉=n!{\delta }_{n,k}$, where $n,k\ge 0$ [[19], Theorem 2.3.1]. The sequence $s_n(x)$ is called the Sheffer sequence for $(g(t),f(t))$ which is denoted by $s_n(x)\sim (g(t),f(t))$ (see [19–22]). For $f(t)\in \mathcal{H}$ and $p(x)\in \mathrm{\Pi }$, we have $〈e^{yt}|p(x)〉=p(y)$, $〈f(t)g(t)|p(x)〉=〈g(t)|f(t)p(x)〉$ and

(see [19–22]). From (1.6), we obtain

where $p^{(k)}(0)$ denotes the k th derivative of $p(x)$ with respect to x at $x=0$. So, by (1.7), we get that $t^{k}p(x)=p^{(k)}(x)=\frac{d^k}{d{x}^k}p(x)$ for all $k\ge 0$ (see [19–22]).

Let $s_n(x)\sim (g(t),f(t))$. Then we have

for all $y\in \mathbb{C}$, where $\overline{f}(t)$ is the compositional inverse of $f(t)$ (see [19–22]). For $s_n(x)\sim (g(t),f(t))$ and $r_n(x)\sim (h(t),\ell (t))$, let

then we have

(see [19–22]).

It is immediate from (1.1)-(1.2), we see that $S_n(x)$ and ${\hat{S}}_n(x)$ are the Sheffer sequences for the pairs

The aim of the present paper is to present several new identities for the Peters polynomials by the use of umbral calculus.

It is well known that

where $S_1(n,m)$ is the Stirling number of the first kind. By (1.11) and (1.12) we have

So

which implies

Thus, we have the following result.

Theorem 1 For all $n\ge 0$,

By (1.6), (1.8), (1.11) and (1.12), we have

where

and

Hence, we can state the following formulas.

Theorem 2 For all $n\ge 0$,

Also, by the definitions, (2.1), (1.11) and (1.12), we have

and

which implies the following formulas.

Theorem 3 For all $n\ge 0$,

More generally, by (2.1) and (2.2) with $p_n(x)={\prod }_{j=1}^r{(1+e^{{\lambda }_{j}t})}^{{\mu }_j}{S}_n(x)={(x)}_n\sim (1,e^t-1)$, we obtain that $S_n(x+y)={\sum }_{j=0}^b{S}_j(x){(y)}_{n-j}\left(\genfrac{}{}{0ex}{}{n}{j}\right)$, and with $p_n(x)={\prod }_{j=1}^r{(\frac{1+e^{{\lambda }_{j}t}}{e^{{\lambda }_{j}t}})}^{{\mu }_j}{\hat{S}}_n(x)={(x)}_n\sim (1,e^t-1)$, we obtain that ${\hat{S}}_n(x+y)={\sum }_{j=0}^b{\hat{S}}_j(x){(y)}_{n-j}\left(\genfrac{}{}{0ex}{}{n}{j}\right)$, which gives the following corollary.

Corollary 1 For all $n\ge 0$,

Note that if $a_n(x)\sim (g(t),f(t))$, then $f(t)a_n(x)=n{a}_{n-1}(x)$, Thus, by (1.11) and (1.12), we have that $S_n(x+1)-S_n(x)=(e^t-1)S_n(x)=n{S}_{n-1}(x)$ and ${\hat{S}}_n(x+1)-{\hat{S}}_n(x)=(e^t-1){\hat{S}}_n(x)=n{\hat{S}}_{n-1}(x)$, which give the following recurrences.

Proposition 1 For all $n\ge 1$,

Note that for $a_n(x)\sim (g(t),f(t))$, we have that $a_{n+1}(x)=(x-g^{\prime }(t)/g(t))\frac{1}{f^{\prime }(t)}{a}_n(x)$. In the case (1.11), we obtain $S_{n+1}(x)=x{S}_n(x-1)-e^{-t}\frac{g^{\prime }(t)}{g(t)}{S}_n(x)$ with $g(t)={\prod }_{i=1}^r{(1+e^{{\lambda }_{j}t})}^{{\mu }_j}$. Since $\frac{g^{\prime }(t)}{g(t)}={\sum }_{i=1}^r\frac{{\lambda }_i{\mu }_i{e}^{{\lambda }_{i}t}}{1+e^{{\lambda }_{i}t}}$ and by (2.3), we get

where $e_i=(0,\dots ,0,1,0,\dots ,0)$ is a vector with 1 in the i th coordinate. Thus,

On the other hand, by Theorem 2, we have

(note that $E_n(x)=\frac{2}{1+e^t}{x}^n={(E+x)}^n={\sum }_{j=0}^n\left(\genfrac{}{}{0ex}{}{n}{j}\right)E_j{x}^{n-j}$ and $\frac{2}{1+e^{{\lambda }_{j}t}}{x}^j={\lambda }_i^j{E}_i(x/{\lambda }_i)$), which implies

Thus, by (3.1), we can state the following result.

Theorem 4 For all $n\ge 0$,

As a corollary, we get the following identity.

Corollary 2 For all $n\ge 0$,

In the case (1.12), we obtain ${\hat{S}}_{n+1}(x)=x{\hat{S}}_n(x-1)-e^{-t}\frac{g^{\prime }(t)}{g(t)}{\hat{S}}_n(x)$ with $g(t)={\prod }_{i=1}^r{(\frac{1+e^{{\lambda }_{j}t}}{e^{{\lambda }_{i}t}})}^{{\mu }_j}$. Since $\frac{g^{\prime }(t)}{g(t)}={\sum }_{i=1}^r\frac{{\lambda }_i{\mu }_i{e}^{{\lambda }_{i}t}}{1+e^{{\lambda }_{i}t}}-{\sum }_{i=1}^r{\lambda }_i{\mu }_i$ and by (2.4), we get

where $\mathit{\lambda }\mathit{\mu }={\sum }_{j=1}^r{\lambda }_j{\mu }_j$ and

So

On the other hand, by Theorem 2, we have

Therefore, by (3.2), we have the following result.

Theorem 5 For all $n\ge 0$,

As a corollary, we get the following identity.

Corollary 3 For all $n\ge 0$,

Recall that for $a_n(x)\sim (g(t),f(t))$, we have $\frac{d}{dx}{a}_n(x)={\sum }_{\ell =0}^{n-1}\left(\genfrac{}{}{0ex}{}{n}{\ell }\right)〈\overline{f}(t)|x^{n-\ell }〉a_{\ell }(x)$. Hence, in the case (1.11), namely $a_n(x)=S_n(x)$, we have

which implies $d/dx{S}_n(x)=n!{\sum }_{\ell =0}^{n-1}\frac{{(-1)}^{n-\ell -1}}{\ell !(n-\ell )}{S}_{\ell }(x)$. In the same way, we obtain the case ${\hat{S}}_n(x)$, which leads to the following result.

Theorem 6 For all $n\ge 1$,

Now we find another recurrence relation by using the derivative operator. For $n\ge 1$, by (1.11) we have