Value distribution of q-difference differential polynomials of entire functions

For a complex value $q\ne 0,1$, and a transcendental entire function $f(z)$ with order, $0<\sigma (f)<\mathrm{\infty }$, we study the value distribution of q-difference differential polynomials ${[f^n(z)(f(qz)-f(z))]}^{(k)}$ and ${[f(z)f(qz)]}^{(k)}$.

MSC:30D35, 39A05.

A meromorphic function $f(z)$ means meromorphic in the complex plane ℂ. If no poles occur, then $f(z)$ reduces to an entire function. For every real number $x\ge 0$, we define ${log}^{+}x:=max\{0,logx\}$. Assume that $n(r,f)$ counts the number of poles of f in $|z|<r$, each pole according to its multiplicity, and that $\overline{n}(r,f)$ counts the number of the distinct poles of f in $|z|<r$, ignoring the multiplicity. The characteristic function of $f(z)$ is defined by

where

and

The notation $\overline{N}(r,f)$ is similarly defined with $\overline{n}(r,f)$ instead of $n(r,f)$. More notations and definitions of the Nevanlinna value distribution theory of meromorphic functions can be found in [1, 2].

A meromorphic function $\alpha (z)$ is called a small function with respect to $f(z)$, if $T(r,\alpha )=S(r,f)$, where $S(r,f)$ denotes any quantity satisfying $S(r,f)=o(T(r,f))$ as $r\to \mathrm{\infty }$ outside a possible exceptional set E of finite logarithmic measure. The order and the exponent of convergence of zeros of meromorphic function $f(z)$ is, respectively, defined as

The difference operators for a meromorphic function $f(z)$ are defined as

A Borel exceptional value of $f(z)$ is any value $a\in \mathbb{C}\cup \{\mathrm{\infty }\}$ satisfying $\lambda (f-a)<\sigma (f)$, where $\lambda (f-\mathrm{\infty })$ means $\lambda (\frac{1}{f})$.

Recently, the difference variant of the Nevanlinna theory has been established independently in [3–6]. Using these theories, value distributions of difference polynomials have been studied by many papers. For example, Laine and Yang [7] proved that if $f(z)$ is a transcendental entire function of finite order, c is a nonzero complex constant and $n\ge 2$, then $f^n(z)f(z+c)$ takes every nonzero value infinitely often.

Chen [8] considered the value distribution of $f(z)f(z+c)$ and obtained the following theorem.

Theorem A [[8], Corollary 1.3]

Let $f(z)$ be a transcendental entire function of finite order, and let c be a nonzero complex constant. If $f(z)$ has the Borel exceptional value 0, then $H(z)=f(z)f(z+c)$ takes every nonzero value $a\in \mathbb{C}$ infinitely often.

Chen [9] considered zeros of difference product $H_n(z)=f^n(z){\mathrm{\Delta }}_{c}f(z)$ and gave some conditions that guarantee $H_n(z)$ has finitely many zeros or infinitely many zeros.

Theorem B [[9], Theorem 1]

Let $f(z)$ be a transcendental entire function of finite order and $c\in \mathbb{C}\setminus \{0\}$ be a constant such that $f(z+c)\not\equiv f(z)$. Set $H_n(z)=f^n(z){\mathrm{\Delta }}_{c}f(z)$ where ${\mathrm{\Delta }}_{c}f(z)=f(z+c)-f(z)$, $n\ge 2$ is an integer. Then the following statements hold.

1. (1)

   If $f(z)$ satisfies $\sigma (f)\ne 1$, or has infinitely many zeros, then $H_n(z)$ has infinitely many zeros.

2. (2)

   If $f(z)$ has only finitely many zeros and $\sigma (f)=1$, then $H_n(z)$ has only finitely many zeros.

The zero distribution of differential polynomials is a classical topic in the theory of meromorphic functions. Hayman [[10], Theorem 10] firstly considered the value distribution of $f^n{f}^{\prime }-1$, where f is a transcendental function.

Recently, Liu, Liu and Cao [11] investigated the zeros of ${[f{(z)}^{n}f(z+c)]}^{(k)}-\alpha (z)$ and ${[f{(z)}^n{\mathrm{\Delta }}_{c}f(z)]}^{(k)}-\alpha (z)$, where $\alpha (z)$ is a nonzero small function with respect to $f(z)$.

Theorem C [[11], Theorems 1.1 and 1.3]

Let $f(z)$ be a transcendental entire function of finite order and $\alpha (z)$ be a nonzero small function with respect to $f(z)$. If $n\ge k+2$, then ${[f{(z)}^{n}f(z+c)]}^{(k)}-\alpha (z)$ has infinitely many zeros. If $f(z)$ is not a periodic function with period c and $n\ge k+3$, then ${[f{(z)}^n{\mathrm{\Delta }}_{c}f(z)]}^{(k)}-\alpha (z)$ has infinitely many zeros.

The main purpose of this paper is to consider a transcendental entire function $f(z)$ with positive and finite order and obtain some results on the value distributions of the q-difference differential polynomials ${[f^n(z)(f(qz)-f(z))]}^{(k)}$ and ${[f(z)f(qz)]}^{(k)}$. The first theorem will consider what conditions guarantee that ${[f^n(z){\mathrm{\nabla }}_{q}f(z)]}^{(k)}$ has infinitely many zeros.

Theorem 1.1 Let $f(z)$ be a transcendental entire function of finite and positive order $\sigma (f)$, $q\in \mathbb{C}\setminus \{0,1\}$ be a constant such that $q^{\sigma (f)}\ne 1$ and $f(z)\not\equiv f(qz)$. Set $H(z)={[f^n(z){\mathrm{\nabla }}_{q}f(z)]}^{(k)}$, $n\ge 1$ is an integer. If $f(z)$ has finitely many zeros, then $H(z)-\alpha (z)$ has infinitely many zeros, where $\alpha (z)$ is a nonzero small entire function with respect to $f(z)$.

In the following, we will study the value distribution of ${[f(z)f(qz)]}^{(k)}$.

Theorem 1.2 Let $f(z)$ be a transcendental entire function of finite and positive order $\sigma (f)$, a be a finite Borel exceptional value of $f(z)$, $q\in \mathbb{C}\setminus \{0,1\}$ be a constant such that $q^{\sigma (f)}\ne \pm 1$. Set $H(z)={[f(z)f(qz)]}^{(k)}$, then the following statements hold.

1. (1)

   If $a=0$, then 0 is also the Borel exceptional value of $H(z)$. So that $H(z)$ has no nonzero finite Borel exceptional value.

2. (2)

   If $a\ne 0$, then $H(z)$ has no finite Borel exceptional value.

3. (3)

   $H(z)$ takes every nonzero value $c\in \mathbb{C}$ infinitely often and satisfies $\lambda (H-c)=\sigma (f)$.

Using the similar method of the proof of Theorem 1.2(1), we get the following result immediately.

Corollary 1.1 Let $f(z)$ be a transcendental entire function of finite and positive order $\sigma (f)$, $q\in \mathbb{C}\setminus \{0,1\}$ be a constant such that $q^{\sigma (f)}\ne -n$. If 0 is a Borel exceptional value of $f(z)$, then 0 is also the Borel exceptional value of ${[f^n(z)f(qz)]}^{(k)}$.

The following are the well-known Weierstrass factorization and Hadamard factorization theorems.

Lemma 2.1 [12]

If an entire function $f(z)$ has a finite exponent of convergence $\lambda (f)$ for its zero-sequence, then $f(z)$ has a representation in the form

satisfying $\lambda (Q)=\sigma (Q)=\lambda (f)$. Further, if $f(z)$ is of finite order, then $g(z)$ in the above form is a polynomial of degree less or equal to the order of $f(z)$.

Lemma 2.2 [13]

Suppose that $f_1(z),f_2(z),\dots ,f_n(z)$ ($n\ge 2$) are meromorphic functions and $g_1(z),g_2(z),\dots ,g_n(z)$ are entire functions satisfying the following conditions:

1. (1)

   ${\sum }_{j=1}^n{f}_j(z)e^{g_j(z)}\equiv 0$;

2. (2)

   $g_j(z)-g_k(z)$ are not constants for $1\le j<k\le n$;

3. (3)

   For $1\le j\le n$, $1\le h<k\le n$, $T(r,f_j)=o(T(r,e^{g_h-g_k}))$ ($r\to \mathrm{\infty }$, $r\notin E$).

Then $f_j(z)\equiv 0$ ($j=1,2,\dots ,n$).

3.1 Proof of Theorem 1.1

Since $f(z)$ is a transcendental entire function of finite order and has finitely many zeros, then by Lemma 2.1, $f(z)$ can be written as

where $g(z)$ (≢0), $h(z)$ are polynomials. Set

where $a_s,a_{s-1},\dots ,a_0$ are constants, and $a_s\ne 0$. Since $\sigma (f)\ne 0$, then $\sigma (f)=deg(h(z))=s\ge 1$. So

where $g_1(z)$, $g_2(z)$ are nonzero polynomials and

Since $q^{\sigma (f)}=q^s\ne 1$, then $(n+1)h(z)-(nh(z)+h(qz))$ is not a constant. So $H(z)$ is a transcendental entire function, suppose that $H(z)-\alpha (z)$ has finitely many zeros, then by Lemma 2.1, $H(z)-\alpha (z)$ can be written as

Here $g_3(z)$ (≢0), $h_1(z)$ are polynomials. Combing the above equalities, we obtain

Note that $(n+1)h(z)-(nh(z)+h(qz))$ is not a constant and $g_1(z)$, $g_2(z)$, $g_3(z)$ are nonzero polynomials. If $(nh(z)+h(qz))-h_1(z)$ and $(n+1)h(z)-h_1(z)$ are not constants, then by (3.1) and Lemma 2.2, we obtain

This is a contradiction.

If $(nh(z)+h(qz))-h_1(z)=c$, where c is a constant, then (3.1) can be rewritten as

By (3.2) and Lemma 2.2, we obtain

This is a contradiction.

If $(n+1)h(z)-h_1(z)=c$, where c is a constant, then using the same method as above, we also obtain a contradiction.

Hence $H(z)-\alpha (z)$ has infinitely many zeros.

3.2 Proof of Theorem 1.2

Since $f(z)$ is a transcendental entire function of finite and positive order with a Borel exceptional value a, then by Lemma 2.1, $f(z)$ can be written as

Here s is a positive integer, α is a nonzero constant, $g(z)$ is a nonzero entire function satisfying $\sigma (g)<\sigma (f)=s$, thus

Since $q^{\sigma (f)}=q^s\ne \pm 1$, $g(z)$ is a nonzero entire function satisfying $\sigma (g)<s$, $f(z)f(qz)$ is a transcendental entire function and $\sigma (f(z)f(qz))=s$, and by the classical result of Nevanlinna theory, we get $\sigma (H)=\sigma (f(z)f(qz))=s$. Then

Here $g_1(z)$, $g_2(z)$, $g_3(z)$ are differential polynomials of $g(z)$, $g(qz)$ and $\sigma (g_i(z))<s$, $i=1,2,3$.

Case 1. $a=0$, by the above equality, we get

Since $q^{\sigma (f)}=q^s\ne -1$ and $\sigma (g_3(z))<s$, this implies that 0 is the Borel exceptional value of $H(z)$.

Case 2. $a\ne 0$, suppose $H(z)$ has a finite Borel exceptional value b, then by Lemma 2.1, $H(z)$ can be written as

Here β is a nonzero constant, $h(z)$ is a nonzero entire function satisfying $\sigma (h)<\sigma (H)=s$. Combing the above equalities, we obtain

Since $q^{\sigma (f)}=q^s\ne \pm 1$, we have $\alpha q^s\ne \alpha \ne \alpha (1+q^s)$.

If $\alpha q^s\ne \beta$, $\alpha \ne \beta$, $\alpha (1+q^s)\ne \beta$. By (3.3) and Lemma 2.2, we obtain

This is a contradiction.

If $\alpha q^s=\beta$, then (3.3) can be rewritten as

By (3.4) and Lemma 2.2, we obtain

Which is a contradiction.

If $\alpha =\beta$ or $\alpha (1+q^s)=\beta$, then using the same method as above, we also obtain a contradiction.

Case 3. From Case 1 and Case 2, we get that if $f(z)$ has a finite Borel exceptional value, then any nonzero finite value c must not be the Borel exceptional value of $H(z)$, so $H(z)$ takes every nonzero value $c\in \mathbb{C}$ infinitely often, since $\sigma (H)=s$, then $\lambda (H-c)=\sigma (H)=\sigma (f)$.

The proof of Theorem 1.2 is completed.

This research was partly supported by the NSFC (no. 11101201, 11301260), Foundation of Post Ph.D. of Jiangxi, the NSF of Jiangxi (no. 20122BAB211001, 20132BAB211003) and NSF of education department of Jiangxi (no. GJJ13077, GJJ13078) of China.

Authors and Affiliations

1. Department of Mathematics, Nanchang University, Nanchang, Jiangxi, 330031, P.R. China

   Na Xu, Ting-Bin Cao & Kai Liu

Corresponding author

Correspondence to Ting-Bin Cao.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All authors drafted the manuscript, read and approved the final manuscript.

Open Access This article is distributed under the terms of the Creative Commons Attribution 2.0 International License ( https://creativecommons.org/licenses/by/2.0 ), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Reprints and permissions