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Degenerate q-Euler polynomials
Advances in Difference Equations volume 2015, Article number: 246 (2015)
Abstract
Recently, some identities of degenerate Euler polynomials arising from p-adic fermionic integrals on \(\mathbb{Z}_{p}\) were introduced in Kim and Kim (Integral Transforms Spec. Funct. 26(4):295-302, 2015). In this paper, we study degenerate q-Euler polynomials which are derived from p-adic q-integrals on \(\mathbb{Z}_{p}\).
1 Introduction
Let p be a fixed odd prime number. Throughout this paper, \(\mathbb{Z}_{p}\), \(\mathbb{Q}_{p}\) and \(\mathbb{C}_{p}\) will denote the ring of p-adic integers, the field of p-adic rational numbers and the completion of algebraic closure of \(\mathbb{Q}_{p}\), respectively. Let \(\nu_{p}\) be the normalized exponential valuation in \(\mathbb{C}_{p}\) with \(\vert p\vert _{p}=p^{-\nu_{p} (p )}=\frac{1}{p}\).
Let q be an indeterminate in \(\mathbb{C}_{p}\) such that \(\vert 1-q\vert _{p}< p^{-\frac{1}{p-1}}\). The q-extension of x is defined as \([x ]_{q}=\frac{1-q^{x}}{1-q}\). Note that \(\lim_{q\rightarrow1} [x ]_{q}=x\). For \(f\in C (\mathbb{Z}_{p})\) = {\(f\mid, f\) is a \(\mathbb{C}_{p}\)-valued continuous function on \(\mathbb{Z}_{p}\)}, the fermionic p-adic q-integral on \(\mathbb{Z}_{p}\) is defined by Kim to be
where \([x ]_{-q}=\frac{1- (-q )^{x}}{1+q}\).
By (1.1), we easily get
and
where \(f_{n} (x )=f (x+n )\) (see [1–16]).
The ordinary fermionic p-adic integral on \(\mathbb{Z}_{p}\) is defined as
The degenerate Euler polynomials of order r (\(\in\mathbb{N}\)) are defined by the generating function to be
where \(\lambda,t\in \mathbb{Z}_{p}\) such that \(\vert \lambda t\vert _{p}< p^{-\frac {1}{p-1}}\).
From (1.5), we have
where \(E_{n}^{ (r )} (x )\) are the higher-order Euler polynomials.
Thus, by (1.6), we get
When \(x=0\), \(\mathcal{E}_{n}^{ (r )} (\lambda )=\mathcal{E}_{n}^{ (r )} (0\mid\lambda )\) are called the higher-order degenerate Euler numbers, while \(\lim_{\lambda\rightarrow0}\mathcal{E}_{n}^{ (r )} (\lambda )=E_{n}^{ (r )}\) are called the higher-order Euler numbers.
In [10], it was shown that
where \((x )_{n}=x (x-1 )\cdots (x-n+1 )\) and \(n\in\mathbb{Z}_{\ge0}\).
In this paper, we study q-extensions of the degenerate Euler polynomials and give some formulae and identities of those polynomials which are derived from the fermionic p-adic q-integrals on \(\mathbb{Z}_{p}\).
2 Some identities of q-analogues of higher-order degenerate Euler polynomials
In this section, we assume that \(\lambda,t\in \mathbb{Z}_{p}\) with \(\vert \lambda t\vert _{p}< p^{-\frac{1}{p-1}}\). From (1.2), we have
Now, we define a q-analogue of degenerate Euler polynomials of order r as follows:
Thus, by (2.2), we easily get
where \(E_{n,q}^{ (r )} (x )\) are called the higher-order q-Euler polynomials (see [15–17]). Thus, by (2.3), we get
For \(\lambda\in\mathbb{C}_{p}\) with \(\lambda\neq1\), the Frobenius-Euler polynomials of order r are defined by the generating function to be
By replacing λ by \(-q^{-1}\), we get
Now, we define the degenerate Frobenius-Euler polynomials of order r as follows:
From (2.6), we note that
Thus, by (2.7), we get
Now, we define
Therefore, by (2.6) and (2.11), we obtain the following theorem.
Theorem 2.1
For \(n\ge0\), we have
where \(h_{n}^{ (r )} (x,u\mid\lambda )\) are called the degenerate Frobenius-Euler polynomials of order r.
It is not difficult to show that
where \(S_{1} (n,l )\) is the Stirling number of the first kind.
We observe that
Thus, by (2.13), we get
By comparing the coefficients on both sides of (2.14), we get
From Theorem 2.1, (2.12) and (2.15), we note that
Therefore, by (2.16), we obtain the following theorem.
Theorem 2.2
For \(n\geq0\), we have
In particular,
By replacing t by \((e^{\lambda t}-1 )/\lambda\) in (2.2), we get
where \(S_{2} (m,n )\) is the Stirling number of the second kind.
Thus, by (2.17), we obtain the following theorem.
Theorem 2.3
For \(m\ge0\), we have
In particular,
When \(r=1\), \(\mathcal{E}_{n,q} (x\mid\lambda )=\mathcal {E}_{n,q}^{ (1 )} (x\mid\lambda )\) are called the degenerate q-Euler polynomials. In particular, \(x=0\), \(\mathcal{E}_{n,q} (\lambda )=\mathcal{E}_{n,q} (0\mid \lambda )\) are called the degenerate q-Euler numbers. \(h_{n} (x,u\mid\lambda )=h_{n}^{ (1 )} (x,u\mid\lambda )\) are called the degenerate Frobenius-Euler polynomials. When \(x=0\), \(h_{n} (u\mid\lambda )=h_{n} (0,u\mid\lambda )\) are called the degenerate Frobenius-Euler numbers.
From (1.2), we have
Thus, by (2.18), we get
and
For \(d\in\mathbb{N}\), by (1.3), we get
Let \(d\equiv1\ (\operatorname{mod}{2})\). Then we have
For \(d\in\mathbb{N}\) with \(d\equiv0\ (\operatorname{mod}{2})\), we get
Therefore, by (2.22) and (2.23), we obtain the following theorem.
Theorem 2.4
Let \(d\in\mathbb{N}\) and \(n\geq0\).
-
(i)
For \(d\equiv1\ (\operatorname{mod}{2})\), we have
$$q^{d}h_{n} \bigl(d,-q^{-1}\mid\lambda \bigr)+h_{n} \bigl(-q^{-1}\mid \lambda \bigr)= [2 ]_{q}\sum_{l=0}^{d-1} (-1 )^{l}q^{l} (l\mid\lambda )_{n}. $$ -
(ii)
For \(d\equiv0\ (\operatorname{mod}{2})\), we have
$$q^{d}h_{n} \bigl(d,-q^{-1}\mid\lambda \bigr)-h_{n} \bigl(-q^{-1}\mid \lambda \bigr)= [2 ]_{q}\sum_{l=0}^{d-1} (-1 )^{l-1}q^{l} (l\mid\lambda )_{n}. $$
Corollary 2.5
Let \(d\in\mathbb{N}\) and \(n\geq0\).
-
(i)
For \(d\equiv1\ (\operatorname{mod}{2})\), we have
$$q^{d}E_{n,q} (d\mid\lambda )+E_{n,q} (\lambda )= [2 ]_{q}\sum_{l=0}^{d-1} (-1 )^{l}q^{l} (l\mid\lambda )_{n}. $$ -
(ii)
For \(d\equiv0\ (\operatorname{mod}{2})\), we have
$$q^{d}E_{n,q} (d\mid\lambda )-E_{n,q} (\lambda )= [2 ]_{q}\sum_{l=0}^{d-1} (-1 )^{l-1}q^{l} (l\mid \lambda )_{n}. $$
From (1.1), we note that
where \(d\in\mathbb{N}\) with \(d\equiv1\ (\operatorname{mod}{2})\).
By (2.24), we get
where \(d\in\mathbb{N}\) with \(d\equiv1\ (\operatorname{mod}{2})\) and \(n\geq0\).
Therefore, by (2.25), we obtain the following theorem.
Theorem 2.6
For \(n\geq0\), \(d\in\mathbb{N}\) with \(d\equiv1\ (\operatorname{mod}{2})\), we have
Moreover,
Now, we consider the degenerate q-Euler polynomials of the second kind as follows:
From (2.26), we note that
When \(x=0\), \(\hat{\mathcal{E}}_{n,q} (\lambda )=\hat{\mathcal {E}}_{n,q} (0\mid\lambda )\) are called the degenerate q-Euler numbers of the second kind.
By (2.26), we get
Thus, from (2.28), we have
We observe that
From (2.30), we have
By replacing t by \(\frac{e^{\lambda t}-1}{\lambda}\) in (2.27), we get
On the other hand, we have
From (2.32) and (2.33), we note that
Therefore, by (2.29) and (2.34), we obtain the following theorem.
Theorem 2.7
For \(n\geq0\), we have
and
It is easy to show that
From (2.35), we have
and
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Acknowledgements
This paper is supported by Grant No. 14-11-00022 of Russian Scientific Fund.
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Kim, T., Kim, D.S. & Dolgy, D.V. Degenerate q-Euler polynomials. Adv Differ Equ 2015, 246 (2015). https://doi.org/10.1186/s13662-015-0563-y
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DOI: https://doi.org/10.1186/s13662-015-0563-y