Higher-order Frobenius-Euler and poly-Bernoulli mixed-type polynomials

Kim, Dae San; Kim, Taekyun

doi:10.1186/1687-1847-2013-251

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Published: 20 August 2013

Higher-order Frobenius-Euler and poly-Bernoulli mixed-type polynomials

Dae San Kim¹ &
Taekyun Kim²

Advances in Difference Equations volume 2013, Article number: 251 (2013) Cite this article

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Abstract

In this paper, we consider higher-order Frobenius-Euler polynomials, associated with poly-Bernoulli polynomials, which are derived from polylogarithmic function. These polynomials are called higher-order Frobenius-Euler and poly-Bernoulli mixed-type polynomials. The purpose of this paper is to give various identities of those polynomials arising from umbral calculus.

1 Introduction

For $λ \in C$ with $λ \neq 1$ , the Frobenius-Euler polynomials of order α ( $α \in R$ ) are defined by the generating function to be

{(\frac{1 - λ}{e^{t} - λ})}^{α} e^{x t} = \sum_{n = 0}^{\infty} H_{n}^{(α)} (x | λ) \frac{t^{n}}{n!} (see [1–5]) .

(1.1)

When $x = 0$ , $H_{n}^{(α)} (λ) = H_{n}^{(α)} (0 | λ)$ are called the Frobenius-Euler numbers of order α. As is well known, the Bernoulli polynomials of order α are defined by the generating function to be

{(\frac{t}{e^{t} - 1})}^{α} e^{x t} = \sum_{n = 0}^{\infty} B_{n}^{(α)} (x) \frac{t^{n}}{n!} (see [6–8]) .

(1.2)

When $x = 0$ , $B_{n}^{(α)} = B_{n}^{(α)} (x)$ is called the n th Bernoulli number of order α. In the special case, $α = 1$ , $B_{n}^{(1)} (x) = B_{n} (x)$ is called the n th Bernoulli polynomial. When $x = 0$ , $B_{n} = B_{n} (0)$ is called the n th ordinary Bernoulli number. Finally, we recall that the Euler polynomials of order α are given by

{(\frac{2}{e^{t} + 1})}^{α} e^{x t} = \sum_{n = 0}^{\infty} E_{n}^{(α)} (x) \frac{t^{n}}{n!} (see [9–13]) .

(1.3)

When $x = 0$ , $E_{n}^{(α)} = E_{n}^{(α)} (0)$ is called the n th Euler number of order α. In the special case, $α = 1$ , $E_{n}^{(1)} (x) = E_{n} (x)$ is called the n th ordinary Euler polynomial. The classical polylogarithmic function $L i_{k} (x)$ is defined by

L i_{k} (x) = \sum_{n = 1}^{\infty} \frac{x^{n}}{n^{k}} (k \in Z) (see [7]) .

(1.4)

As is known, poly-Bernoulli polynomials are defined by the generating function to be

\frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} e^{x t} = \sum_{n = 0}^{\infty} B_{n}^{(k)} (x) \frac{t^{n}}{n!} (cf. [7]) .

(1.5)

Let ℂ be the complex number field, and let ℱ be the set of all formal power series in the variable t over ℂ with

F = {f (t) = \sum_{k = 0}^{\infty} \frac{a_{k}}{k!} t^{k} | a_{k} \in C} .

(1.6)

Now, we use the notation $P = C [x]$ . In this paper, $P^{*}$ will be denoted by the vector space of all linear functionals on ℙ. Let us assume that $〈 L | p (x) 〉$ be the action of the linear functional L on the polynomial $p (x)$ , and we remind that the vector space operations on $P^{*}$ are defined by $〈 L + M | p (x) 〉 = 〈 L | p (x) 〉 + 〈 M | p (x) 〉$ , $〈 c L | p (x) 〉 = c 〈 L | p (x) 〉$ , where c is a complex constant in ℂ. The formal power series

f (t) = \sum_{k = 0}^{\infty} \frac{a_{k}}{k!} t^{k} \in F

(1.7)

defines a linear functional on ℙ by setting

〈 f (t) | x^{n} 〉 = a_{n}, for all n \geq 0 (see [14, 15]) .

(1.8)

From (1.7) and (1.8), we note that

〈 t^{k} | x^{n} 〉 = n! δ_{n, k} (see [14, 15]),

(1.9)

where $δ_{n, k}$ is the Kronecker symbol.

Let us consider $f_{L} (t) = \sum_{k = 0}^{\infty} \frac{〈 L | x^{n} 〉}{k!} t^{k}$ . Then we see that $〈 f_{L} (t) | x^{n} 〉 = 〈 L | x^{n} 〉$ , and so $L = f_{L} (t)$ as linear functionals. The map $L \mapsto f_{L} (t)$ is a vector space isomorphism from $P^{*}$ onto ℱ. Henceforth, ℱ will denote both the algebra of formal power series in t and the vector space of all linear functionals on ℙ, and so an element $f (t)$ of ℱ will be thought of as both a formal power series and a linear functional (see [14]). We shall call ℱ the umbral algebra. The umbral calculus is the study of umbral algebra. The order $o (f (t))$ of a nonzero power series $f (t)$ is the smallest integer k, for which the coefficient of $t^{k}$ does not vanish. A series $f (t)$ is called a delta series if $o (f (t)) = 1$ , and an invertible series if $o (f (t)) = 0$ . Let $f (t), g (t) \in F$ . Then we have

〈 f (t) g (t) | p (x) 〉 = 〈 f (t) | g (t) p (x) 〉 = 〈 g (t) | f (t) p (x) 〉 (see [14]) .

(1.10)

For $f (t), g (t) \in F$ with $o (f (t)) = 1$ , $o (g (t)) = 0$ , there exists a unique sequence $S_{n} (x)$ ( $deg S_{n} (x) = n$ ) such that $〈 g (t) f {(t)}^{k} | S_{n} (x) 〉 = n! δ_{n, k}$ for $n, k \geq 0$ . 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 [14, 15]). Let $f (t) \in F$ and $p (t) \in P$ . Then we have

f (t) = \sum_{k = 0}^{\infty} 〈 f (t) | x^{k} 〉 \frac{t^{k}}{k!}, p (x) = \sum_{k = 0}^{\infty} 〈 t^{k} | p (x) 〉 \frac{x^{k}}{k!} .

(1.11)

From (1.11), we note that

p^{(k)} (0) = 〈 t^{k} | p (x) 〉 = 〈 1 | p^{(k)} (x) 〉 .

(1.12)

By (1.12), we get

t^{k} p (x) = p^{(k)} (x) = \frac{d^{k} p (x)}{d x^{k}} (see [14, 15]) .

(1.13)

From (1.13), we easily derive the following equation

e^{y t} p (x) = p (x + y), 〈 e^{y t} | p (x) 〉 = p (y) .

(1.14)

For $p (x) \in P$ , $f (t) \in F$ , it is known that

〈 f (t) | x p (x) 〉 = 〈 \partial_{t} f (t) | p (x) 〉 = 〈 f^{'} (t) | p (x) 〉 (see [14]) .

(1.15)

Let $S_{n} (x) \sim (g (t), f (t))$ . Then we have

\frac{1}{g (\bar{f} (x))} e^{y \bar{f} (t)} = \sum_{n = 0}^{\infty} S_{n} (y) \frac{t^{n}}{n!} for all y \in C,

(1.16)

where $\bar{f} (t)$ is the compositional inverse of $f (t)$ with $\bar{f} (f (t)) = t$ , and

f (t) S_{n} (x) = n S_{n - 1} (x) (see [14, 15]) .

(1.17)

The Stirling number of the second kind is defined by the generating function to be

{(e^{t} - 1)}^{m} = m! \sum_{l = m}^{\infty} S_{2} (l, m) \frac{t^{m}}{m!} (m \in Z_{\geq 0}) .

(1.18)

For $S_{n} (x) \sim (g (t), t)$ , it is well known that

S_{n + 1} (x) = (x - \frac{g^{'} (t)}{g (t)}) S_{n} (x) (n \geq 0) (see [14, 15]) .

(1.19)

Let $S_{n} (x) \sim (g (t), f (t))$ , $r_{n} (x) \sim (h (t), l (t))$ . Then we have

S_{n} (x) = \sum_{m = 0}^{n} C_{n, m} r_{m} (x),

(1.20)

where

C_{n, m} = \frac{1}{m!} 〈 \frac{h (\bar{f} (t))}{g (\bar{f} (t))} l {(\bar{f} (t))}^{m} | x^{n} 〉 (see [14, 15]) .

(1.21)

In this paper, we study higher-order Frobeniuns-Euler polynomials associated with poly-Bernoulli polynomials, which are called higher-order Frobenius-Euler and poly-Beroulli mixed-type polynomials. The purpose of this paper is to give various identities of those polynomials arising from umbral calculus.

2 Higher-order Frobenius-Euler polynomials, associated poly-Bernoulli polynomials

Let us consider the polynomials $T_{n}^{(r, k)} (x | λ)$ , called higher-order Frobenius-Euler and poly-Bernoulli mixed-type polynomials, as follows:

{(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} e^{x t} = \sum_{n = 0}^{\infty} T_{n}^{(r, k)} (x | λ) \frac{t^{n}}{n!},

(2.1)

where $λ \in C$ with $λ \neq 1$ , $r, k \in Z$ .

When $x = 0$ , $T_{n}^{(r, k)} (λ) = T_{n}^{(r, k)} (0 | λ)$ is called the n th higher-order Frobenius-Euler and poly-Bernoulli mixed type number.

From (1.16) and (2.1), we note that

T_{n}^{(r, k)} (x | λ) \sim (g_{r, k} (t) = {(\frac{e^{t} - λ}{1 - λ})}^{r} \frac{1 - e^{- t}}{L i_{k} (1 - e^{- t})}, t) .

(2.2)

By (1.17) and (2.2), we get

t T_{n}^{(r, k)} (x | λ) = n T_{n - 1}^{(r, k)} (x | λ) .

(2.3)

From (2.1), we can easily derive the following equation

\begin{aligned} T_{n}^{(r, k)} (x | λ) & = \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (λ) B_{l}^{(k)} (x) \\ = \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (x | λ) B_{l}^{(k)} . \end{aligned}

(2.4)

By (1.16) and (2.2), we get

T_{n}^{(r, k)} (x | λ) = \frac{1}{g_{r, k} (t)} x^{n} = {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n} .

(2.5)

In [7], it is known that

\frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n} = \sum_{m = 0}^{n} \frac{1}{{(m + 1)}^{k}} \sum_{j = 0}^{m} {(- 1)}^{j} (\binom{m}{j}) {(x - j)}^{n} .

(2.6)

Thus, by (2.5) and (2.6), we get

\begin{aligned} T_{n}^{(r, k)} (x | λ) & = {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n} \\ = \sum_{m = 0}^{\infty} \frac{1}{{(m + 1)}^{k}} \sum_{j = 0}^{m} {(- 1)}^{j} (\binom{m}{j}) {(\frac{1 - λ}{e^{t} - λ})}^{r} {(x - j)}^{n} \\ = \sum_{m = 0}^{n} \frac{1}{{(m + 1)}^{k}} \sum_{j = 0}^{m} {(- 1)}^{j} (\binom{m}{j}) H_{n}^{(r)} (x - j | λ) . \end{aligned}

(2.7)

By (1.1), we easily see that

H_{n}^{(r)} (x | λ) = \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (λ) x^{l} .

(2.8)

Therefore, by (2.7) and (2.8), we obtain the following theorem.

Theorem 2.1 For $r, k \in Z$ , $n \geq 0$ , we have

\begin{aligned} T_{n}^{(r, k)} (x | λ) & = \sum_{m = 0}^{n} \frac{1}{{(m + 1)}^{k}} \sum_{j = 0}^{m} {(- 1)}^{j} (\binom{m}{j}) \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (λ) {(x - j)}^{l} \\ = \sum_{l = 0}^{n} {(\binom{n}{l}) H_{n - l}^{(r)} (λ) \sum_{m = 0}^{\infty} \frac{1}{{(m + 1)}^{k}} \sum_{j = 0}^{m} {(- 1)}^{j} (\binom{m}{j})} {(x - j)}^{l} . \end{aligned}

In [7], it is known that

\frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n} = \sum_{j = 0}^{n} {\sum_{m = 0}^{n - j} \frac{{(- 1)}^{n - m - j}}{{(m + 1)}^{k}} (\binom{n}{j}) m! S_{2} (n - j, m)} x^{j} .

(2.9)

By (2.5) and (2.9), we get

\begin{aligned} T_{n}^{(r, k)} (x | λ) & = {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n} \\ = \sum_{j = 0}^{n} {\sum_{m = 0}^{n - j} \frac{{(- 1)}^{n - m - j}}{{(m + 1)}^{k}} (\binom{n}{j}) m! S_{2} (n - j, m)} {(\frac{1 - λ}{e^{t} - λ})}^{r} x^{j} \\ = \sum_{j = 0}^{n} {\sum_{m = 0}^{n - j} \frac{{(- 1)}^{n - m - j}}{{(m + 1)}^{k}} (\binom{n}{j}) m! S_{2} (n - j, m)} H_{j}^{(r)} (x | λ) . \end{aligned}

(2.10)

Therefore, by (2.8) and (2.10), we obtain the following theorem.

Theorem 2.2 For $r, k \in Z$ , $n \in Z_{\geq 0}$ , we have

T_{n}^{(r, k)} (x | λ) = \sum_{l = 0}^{n} {\sum_{j = l}^{n} \sum_{m = 0}^{n - j} {(- 1)}^{n - m - j} (\binom{n}{j}) (\binom{j}{l}) \frac{m!}{{(m + 1)}^{k}} H_{j - l}^{(r)} (λ) S_{2} (n - j, m)} x^{l} .

From (1.19) and (2.2), we have

T_{n + 1}^{(r, k)} (x | λ) = (x - \frac{g_{r, k}^{'} (t)}{g_{r, k} (t)}) T_{n}^{(r, k)} (x | λ) .

(2.11)

Now, we note that

\begin{aligned} \frac{g_{r, k}^{'} (t)}{g_{r, k} (t)} & = {(log g_{r, k} (t))}^{'} \\ = {(r log (e^{t} - λ) - r log (1 - λ) + log (1 - e^{- t}) - log L i_{k} (1 - e^{t}))}^{'} \\ = r + \frac{r λ}{e^{t} λ} + (\frac{t}{e^{t} - 1}) \frac{L i_{k} (1 - e^{- t}) - L i_{k - 1} (1 - e^{- t})}{t L i_{k} (1 - e^{- t})} . \end{aligned}

(2.12)

By (2.11) and (2.12), we get

\begin{array}{rcl} T_{n + 1}^{(r, k)} (x | λ) & = & x T_{n}^{(r, k)} (x | λ) - r T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} {(\frac{1 - λ}{e^{t} - λ})}^{r + 1} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n} \\ - {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t}) - L i_{k - 1} (1 - e^{- t})}{t (1 - e^{- t})} (\frac{t}{e^{t} - 1}) x^{n} \\ = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \sum_{l = 0}^{n} (\binom{n}{l}) B_{n - l} {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t}) - L i_{k - 1} (1 - e^{- t})}{t (1 - e^{- t})} x^{l} . \end{array}

(2.13)

It is easy to show that

\begin{aligned} \frac{L i_{k} (1 - e^{- t}) - L i_{k - 1} (1 - e^{- t})}{1 - e^{- t}} & = \frac{1}{1 - e^{- t}} \sum_{n = 1}^{\infty} {\frac{{(1 - e^{- t})}^{n}}{n^{k}} - \frac{{(1 - e^{- t})}^{n}}{n^{k - 1}}} \\ = (\frac{1 - e^{- t}}{2^{k}} - \frac{1 - e^{- t}}{2^{k - 1}}) + \dots \\ = (\frac{1}{2^{k}} - \frac{1}{2^{k - 1}}) t + \dots . \end{aligned}

(2.14)

For any delta series $f (t)$ , we have

\frac{f (t)}{t} x^{n} = f (t) \frac{1}{n + 1} x^{n + 1} .

(2.15)

Thus, by (2.13), (2.14) and (2.15), we get

\begin{array}{rcl} T_{n + 1}^{(r, k)} (x | λ) & = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \sum_{l = 0}^{n} (\binom{n}{l}) B_{n - l} \frac{1}{l + 1} {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t}) - L i_{k - 1} (1 - e^{- t})}{1 - e^{- t}} x^{l + 1} \\ = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \sum_{l = 0}^{n} \frac{(\binom{n}{l})}{l + 1} B_{n - l} {T_{l + 1}^{(r, k)} (x | λ) - T_{l + 1}^{(r, k - 1)} (x | λ)} \\ = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \frac{1}{n + 1} \sum_{l = 1}^{n + 1} (\binom{n + 1}{l}) B_{n + 1 - l} {T_{l}^{(r, k)} (x | λ) - T_{l}^{(r, k - 1)} (x | λ)} \\ = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \frac{1}{n + 1} \sum_{l = 0}^{n + 1} (\binom{n + 1}{l}) B_{n + 1 - l} {T_{l}^{(r, k)} (x | λ) - T_{l}^{(r, k - 1)} (x | λ)} \\ = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \frac{1}{n + 1} \sum_{l = 0}^{n + 1} (\binom{n + 1}{l}) B_{l} {T_{n + 1 - l}^{(r, k)} (x | λ) - T_{n + 1 - l}^{(r, k - 1)} (x | λ)} . \end{array}

(2.16)

Therefore, by (2.16), we obtain the following theorem.

Theorem 2.3 For $r, k \in Z$ , $n \in Z_{\geq 0}$ , we have

\begin{aligned} T_{n + 1}^{(r, k)} (x | λ) = & (x - r) T_{n}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n}^{(r + 1, k)} (x | λ) \\ - \frac{1}{n + 1} \sum_{l = 0}^{n + 1} (\binom{n + 1}{l}) B_{l} {T_{n + 1 - l}^{(r, k)} (x | λ) - T_{n + 1 - l}^{(r, k - 1)} (x | λ)} . \end{aligned}

Remark 1 If $r = 0$ , then we have

\sum_{n = 0}^{\infty} B_{n}^{(k)} (x) \frac{t^{n}}{n!} = \frac{L i_{k} (1 - e^{- t})}{(1 - e^{- t})} e^{x t} = \sum_{n = 0}^{\infty} T_{n}^{(0, k)} (x | λ) \frac{t^{n}}{n!} .

(2.17)

Thus, by (2.17), we get $B_{n}^{(k)} (x) = T_{n}^{(0, k)} (x | λ)$ .

From (2.4), we have

\begin{array}{rcl} t x T_{n}^{(r, k)} (x | λ) & = & t (x \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (λ) B_{l}^{(k)} (x)) \\ = & \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (λ) {l x B_{l - 1}^{(k)} (x) + B_{l}^{(k)} (x)} \\ = & n x \sum_{l = 0}^{n - 1} (\binom{n - 1}{l}) H_{n - 1 - l}^{(r)} (λ) B_{l}^{(k)} (x) + \sum_{l = 0}^{n} (\binom{n}{l}) H_{n - l}^{(r)} (λ) B_{l}^{(k)} (x) \\ = & n x T_{n - 1}^{(r, k)} (x | λ) + T_{n}^{(r, k)} (x | λ) . \end{array}

(2.18)

Applying t on both sides of Theorem 2.3, we get

\begin{aligned} (n + 1) T_{n}^{(r, k)} (x | λ) \\ = n x T_{n - 1}^{(r, k)} (x | λ) + T_{n}^{(r, k)} (x | λ) - r n T_{n - 1}^{(r, k)} (x | λ) - \frac{r n λ}{1 - λ} T_{n - 1}^{(r + 1, k)} (x | λ) \\ - \frac{1}{n + 1} \sum_{l = 0}^{n + 1} (\binom{n + 1}{l}) B_{l} {(n + 1 - l) T_{n - l}^{(r, k)} (x | λ) - (n + 1 - l) T_{n - l}^{(r, k - 1)} (x | λ)} . \end{aligned}

(2.19)

Thus, by (2.19), we have

\begin{aligned} (n + 1) T_{n}^{(r, k)} (x | λ) + n (r - \frac{1}{2} - x) T_{n - 1}^{(r, k)} (x | λ) + \sum_{l = 0}^{n - 2} (\binom{n}{l}) B_{n - l} T_{l}^{(r, k)} (x | λ) \\ = - \frac{r λ n}{1 - λ} T_{n - 1}^{(r + 1, k)} (x | λ) + \sum_{l = 0}^{n} (\binom{n}{l}) B_{n - l} T_{l}^{(r, k - 1)} (x | λ) . \end{aligned}

(2.20)

Therefore, by (2.20), we obtain the following theorem.

Theorem 2.4 For $r, k \in Z$ , $n \in Z$ with $n \geq 2$ , we have

\begin{aligned} (n + 1) T_{n}^{(r, k)} (x | λ) + n (r - \frac{1}{2} - x) T_{n - 1}^{(r, k)} (x | λ) + \sum_{l = 0}^{n - 2} (\binom{n}{l}) B_{n - l} T_{l}^{(r, k)} (x | λ) \\ = - \frac{r λ n}{1 - λ} T_{n - 1}^{(r + 1, k)} (x | λ) + \sum_{l = 0}^{n} (\binom{n}{l}) B_{n - l} T_{l}^{(r, k - 1)} (x | λ) . \end{aligned}

From (1.14) and (2.5), we note that

\begin{aligned} T_{n}^{(r, k)} (y | λ) & = 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} e^{y t} | x^{n} 〉 \\ = 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} e^{y t} | x x^{n - 1} 〉 . \end{aligned}

(2.21)

By (1.15) and (2.21), we get

\begin{array}{rcl} T_{n}^{(r, k)} (y | λ) & = & 〈 \partial_{t} ({(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} e^{y t}) | x^{n - 1} 〉 \\ = & 〈 (\partial_{t} {(\frac{1 - λ}{e^{t} - λ})}^{r}) \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} e^{y t} | x^{n - 1} 〉 \\ + 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} (\partial_{t} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}}) e^{y t} | x^{n - 1} 〉 \\ + 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} \partial_{t} e^{y t} | x^{n - 1} 〉 . \end{array}

(2.22)

Therefore, by (2.22), we obtain the following theorem.

Theorem 2.5 For $r, k \in Z$ , $n \geq 1$ , we have

\begin{aligned} T_{n}^{(r, k)} (x | λ) = & (x - r) T_{n - 1}^{(r, k)} (x | λ) - \frac{r λ}{1 - λ} T_{n - 1}^{(r + 1, k)} (x | λ) \\ + \sum_{l = 0}^{n - 1} {{(- 1)}^{n - 1 - l} (\binom{n - 1}{l}) \sum_{m = 0}^{n - 1 - l} {(- 1)}^{m} \frac{(m + 1)!}{{(m + 2)}^{k}} S_{2} (n - 1 - l, m)} H_{l}^{(r)} (x - 1 | λ) . \end{aligned}

Now, we compute $〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} L i_{k} (1 - e^{- t}) | x^{n + 1} 〉$ in two different ways.

On the one hand,

\begin{aligned} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} L i_{k} (1 - e^{- t}) | x^{n + 1} 〉 \\ = 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | (1 - e^{- t}) x^{n + 1} 〉 \\ = 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | x^{n + 1} - {(x - 1)}^{n + 1} 〉 \\ = \sum_{m = 0}^{n} (\binom{n + 1}{m}) {(- 1)}^{n - m} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | x^{m} 〉 \\ = \sum_{m = 0}^{n} (\binom{n + 1}{m}) {(- 1)}^{n - m} 〈 1 | T_{m}^{(r, k)} (x | λ) 〉 \\ = \sum_{m = 0}^{n} (\binom{n + 1}{m}) {(- 1)}^{n - m} T_{m}^{(r, k)} (λ) . \end{aligned}

(2.23)

On the other hand, we get

\begin{aligned} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} L i_{k} (1 - e^{- t}) | x^{n + 1} 〉 \\ = 〈 L i_{k} (1 - e^{- t}) | {(\frac{1 - λ}{e^{t} - λ})}^{r} x^{n + 1} 〉 \\ = 〈 \int_{0}^{t} {(L i_{k} (1 - e^{- s}))}^{'} d s | H_{n + 1}^{(r)} (x | λ) 〉 \\ = 〈 \int_{0}^{t} e^{- s} \frac{L i_{k} (1 - e^{- s})}{(1 - e^{- s})} d s | H_{n + 1}^{(r)} (x | λ) 〉 \\ = \sum_{l = 0}^{n} (\sum_{m = 0}^{l} (\binom{l}{m}) {(- 1)}^{l - m} B_{m}^{(k - 1)}) \frac{1}{l!} 〈 \int_{0}^{t} s^{l} d s | H_{n + 1}^{(r)} (x | λ) 〉 \\ = \sum_{l = 0}^{n} \sum_{m = 0}^{l} (\binom{l}{m}) {(- 1)}^{l - m} \frac{B_{m}^{(k - 1)}}{(l + 1)!} 〈 t^{l + 1} | H_{n + 1}^{(r)} (x | λ) 〉 \\ = \sum_{l = 0}^{n} \sum_{m = 0}^{l} (\binom{l}{m}) (\binom{n + 1}{l + 1}) {(- 1)}^{l - m} B_{m}^{(k - 1)} H_{n - l}^{(r)} (λ) . \end{aligned}

(2.24)

Therefore, by (2.23) and (2.24), we obtain the following theorem.

Theorem 2.6 For $r, k \in Z$ , $n \in Z_{\geq 0}$ , we have

\begin{aligned} \sum_{m = 0}^{n} (\binom{n + 1}{m}) {(- 1)}^{n - m} T_{m}^{(r, k)} (λ) \\ = \sum_{l = 0}^{n} \sum_{m = 0}^{l} {(- 1)}^{l - m} (\binom{l}{m}) (\binom{n + 1}{l + 1}) B_{m}^{(k - 1)} H_{n - l}^{(r)} (λ) . \end{aligned}

Now, we consider the following two Sheffer sequences:

\begin{aligned} T_{n}^{(r, k)} (x | λ) \sim ({(\frac{e^{t} - λ}{1 - λ})}^{r} \frac{1 - e^{- t}}{L i_{k} (1 - e^{- t})}, t), \\ B^{(s)} \sim ({(\frac{e^{t} - 1}{t})}^{s}, t), \end{aligned}

(2.25)

where $s \in Z_{\geq 0}$ , $r, k \in Z$ and $λ \in C$ with $λ \neq 1$ . Let us assume that

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} C_{n \cdot m} B_{m}^{(s)} (x) .

(2.26)

By (1.21) and (2.26), we get

\begin{array}{rcl} C_{n, m} & = & \frac{1}{m!} 〈 {(\frac{e^{t} - 1}{t})}^{s} {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} t^{m} | x^{n} 〉 \\ = & \frac{1}{m!} 〈 {(\frac{e^{t} - 1}{t})}^{s} {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | t^{m} x^{n} 〉 \\ = & (\binom{n}{m}) 〈 {(\frac{e^{t} - 1}{t})}^{s} {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | x^{n - m} 〉 \\ = & (\binom{n}{m}) \sum_{l = 0}^{n - m} \frac{s!}{(l + s)!} S_{2} (l + s, s) 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | t^{l} x^{n - m} 〉 \\ = & (\binom{n}{m}) \sum_{l = 0}^{n - m} \frac{s! l!}{(l + s)!} \frac{{(n - m)}_{l}}{l!} S_{2} (l + s, s) 〈 1 | T_{n - m - l}^{(r, k)} (x | λ) 〉 \\ = & (\binom{n}{m}) \sum_{l = 0}^{n - m} \frac{(\binom{n - m}{l})}{(\binom{s + l}{l})} S_{2} (l + s, s) T_{n - m - l}^{(r, k)} (λ) . \end{array}

(2.27)

Therefore, by (2.26) and (2.27), we obtain the following theorem.

Theorem 2.7 For $r, k \in Z$ , $s \in Z_{\geq 0}$ , we have

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} {(\binom{n}{m}) \sum_{l = 0}^{n - m} \frac{(\binom{n - m}{l})}{(\binom{s + l}{l})} S_{2} (l + s, s) T_{n - m - l}^{(r, k)} (λ)} B_{m}^{(s)} (x) .

From (1.3) and (2.1), we note that

\begin{aligned} T_{n}^{(r, k)} (x | λ) \sim ({(\frac{e^{t} - λ}{1 - λ})}^{r} \frac{1 - e^{- t}}{L i_{k} (1 - e^{- t})}, t), \\ E_{n}^{(r, s)} (x) \sim ({(\frac{e^{t} + 1}{2})}^{s}, t), \end{aligned}

(2.28)

where $r, k \in Z$ , $s \in Z_{\geq 0}$ .

By the same method, we get

T_{n}^{(r, k)} (x | λ) = \frac{1}{2^{s}} \sum_{m = 0}^{n} {(\binom{n}{m}) \sum_{j = 0}^{s} (\binom{s}{j}) T_{n - m}^{(r, k)} (j)} E_{m}^{(s)} (x) .

(2.29)

From (1.1) and (2.1), we note that

\begin{aligned} T_{n}^{(r, k)} (x | λ) \sim ({(\frac{e^{t} - λ}{1 - λ})}^{r} \frac{1 - e^{- t}}{L i_{k} (1 - e^{- t})}, t), \\ H_{n}^{(s)} (x | μ) \sim ({(\frac{e^{t} - μ}{1 - μ})}^{s}, t), \end{aligned}

(2.30)

where $r, k \in Z$ , and $λ, μ \in C$ with $λ \neq 1$ , $μ \neq 1$ , $s \in Z_{\geq 0}$ .

Let us assume that

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} C_{n, m} H_{m}^{(s)} (x | μ) .

(2.31)

By (1.21) and (2.31), we get

\begin{array}{rcl} C_{n, m} & = & \frac{1}{m!} 〈 {(\frac{e^{t} - μ}{1 - μ})}^{s} {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} t^{m} | x^{n} 〉 \\ = & \frac{(\binom{n}{m})}{{(1 - μ)}^{s}} 〈 {(e^{t} - μ)}^{s} | {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n - m} 〉 \\ = & \frac{(\binom{n}{m})}{{(1 - μ)}^{s}} \sum_{j = 0}^{s} (\binom{s}{j}) {(- μ)}^{s - j} 〈 e^{j t} | T_{n - m}^{(r, k)} (x | λ) 〉 \\ = & \frac{(\binom{n}{m})}{{(1 - μ)}^{s}} \sum_{j = 0}^{s} (\binom{s}{j}) {(- μ)}^{s - j} T_{n - m}^{(r, k)} (j | λ) . \end{array}

(2.32)

Therefore, by (2.31) and (2.32), we obtain the following theorem.

Theorem 2.8 For $r, k \in Z$ , $s \in Z_{\geq 0}$ , we have

T_{n}^{(r, k)} (x | λ) = \frac{1}{{(1 - μ)}^{s}} \sum_{m = 0}^{n} {(\binom{n}{m}) \sum_{j = 0}^{s} (\binom{s}{j}) {(- μ)}^{s - j} T_{n - m}^{(r, k)} (j | λ)} H_{m}^{(s)} (x | μ) .

It is known that

\begin{aligned} T_{n}^{(r, k)} (x | λ) \sim ({(\frac{e^{t} - λ}{1 - λ})}^{r} \frac{1 - e^{- t}}{L i_{k} (1 - e^{- t})}, t), \\ {(x)}_{n} \sim (1, e^{t} - 1) . \end{aligned}

(2.33)

Let

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} C_{n, m} {(x)}_{m} .

(2.34)

Then, by (1.21) and (2.34), we get

\begin{array}{rcl} C_{n, m} & = & \frac{1}{m!} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} {(e^{t} - 1)}^{m} | x^{n} 〉 \\ = & \sum_{l = 0}^{\infty} \frac{S_{2} (l + m, m)}{(l + m)!} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | t^{m + l} x^{n} 〉 \\ = & \sum_{l = 0}^{n - m} \frac{S_{2} (l + m, m)}{(l + m)!} {(n)}_{m + l} 〈 1 | {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n - m - l} 〉 \\ = & \sum_{l = 0}^{n - m} (\binom{n}{l + m}) S_{2} (l + m, m) T_{n - m - l}^{(r, k)} (λ) . \end{array}

(2.35)

Therefore, by (2.34) and (2.35), we obtain the following theorem.

Theorem 2.9 For $r, k \in Z$ , we have

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} {\sum_{l = 0}^{n - m} (\binom{n}{l + m}) S_{2} (l + m, m) T_{n - m - l}^{(r, k)} (λ)} {(x)}_{m} .

Finally, we consider the following two Sheffer sequences:

\begin{aligned} T_{n}^{(r, k)} (x | λ) \sim ({(\frac{e^{t} - λ}{1 - λ})}^{r} \frac{1 - e^{- t}}{L i_{k} (1 - e^{- t})}, t), \\ x^{[n]} \sim (1, 1 - e^{- t}), \end{aligned}

(2.36)

where $x^{[n]} = x (x + 1) \dots (x + n - 1)$ .

Let us assume that

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} C_{n, m} x^{[m]} .

(2.37)

Then, by (1.21) and (2.37), we get

\begin{array}{rcl} C_{n, m} & = & \frac{1}{m!} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} {(1 - e^{- t})}^{m} | x^{n} 〉 \\ = & \sum_{l = 0}^{\infty} \frac{{(- 1)}^{l} S_{2} (l + m, m)}{(l + m)!} 〈 {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} | t^{m + l} x^{n} 〉 \\ = & \sum_{l = 0}^{n - m} \frac{{(- 1)}^{l} S_{2} (l + m, m)}{(l + m)!} {(n)}_{m + l} 〈 1 | {(\frac{1 - λ}{e^{t} - λ})}^{r} \frac{L i_{k} (1 - e^{- t})}{1 - e^{- t}} x^{n - m - l} 〉 \\ = & \sum_{l = 0}^{n - m} {(- 1)}^{l} (\binom{n}{l + m}) S_{2} (l + m, m) T_{n - m - l}^{(r, k)} (λ) . \end{array}

(2.38)

Therefore, by (2.37) and (2.38), we obtain the following theorem.

Theorem 2.10 For $r, k \in Z$ , $n \geq 0$ , we have

T_{n}^{(r, k)} (x | λ) = \sum_{m = 0}^{n} {\sum_{l = 0}^{n - m} {(- 1)}^{l} (\binom{n}{l + m}) S_{2} (l + m, m) T_{n - m - l}^{(r, k)} (λ)} x^{[m]} .

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Acknowledgements

This work was supported by the National Research Foundation of Korea (NRF) grant, funded by the Korea government (MOE) (No. 2012R1A1A2003786).

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Department of Mathematics, Sogang University, Seoul, 121-742, Republic of Korea
Dae San Kim
Department of Mathematics, Kwangwoon University, Seoul, 139-701, Republic of Korea
Taekyun Kim

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Kim, D.S., Kim, T. Higher-order Frobenius-Euler and poly-Bernoulli mixed-type polynomials. Adv Differ Equ 2013, 251 (2013). https://doi.org/10.1186/1687-1847-2013-251

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Received: 11 July 2013
Accepted: 06 August 2013
Published: 20 August 2013
DOI: https://doi.org/10.1186/1687-1847-2013-251

Higher-order Frobenius-Euler and poly-Bernoulli mixed-type polynomials

Abstract

1 Introduction

2 Higher-order Frobenius-Euler polynomials, associated poly-Bernoulli polynomials

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