Growth and fixed points of solutions and their arbitrary-order derivatives of higher-order linear differential equations in the unit disc

In this paper, we investigate the growth and fixed points of solutions of higher-order linear differential equations in the unit disc. We extend the coefficient conditions to a type of one-constant-control coefficient comparison and obtain the same estimates of iterated order of solutions. We also obtain better estimates by providing a precise value of iterated order of solution instead of a range of that in the case of coefficient characteristic function comparison. Moreover, we utilize iteration to investigate and estimate the fixed points of solutions’ arbitrary-order derivatives with higher-order equations \(f^{(k)}+A_{k-1}(z)f^{(k-1)}+{\cdots }+A_{1}(z)f'+A_{0}(z)f=0\) and provide a concise method to judge if the items generated by the iteration do not vanish identically and ensure the iteration proceeds. Our results are an improvement over those by B. Belaïdi, T. B. Cao, G. W. Zhang and A. Chen.

In this paper, we assume that the reader is familiar with the fundamental results and the standard notations of Nevanlinna’s value distribution theory in the unit disc \(\mathbb{D}=\{z\in \mathbb{C}:|z|<1\}\) (see [1–4]). As for the definition of the iterated order of meromorphic function, we know that for \(r\in [0,1)\), \(\exp _{1}r=\mathrm {e}^{r}\) and \(\exp _{n+1}r=\exp (\exp _{n}r), n\in \mathbb{N}\), and for all r sufficiently large in \((0,1)\), \(\log _{1}r=\log r\) and \(\log _{n+1}r=\log (\log _{n}r), n\in \mathbb{N}\). Moreover, we denote \(\exp _{0}r=r, \log _{0}r=r, \exp _{-1}r=\log _{1}r, \log _{-1}r= \exp _{1}r\). Then, let us recall the following definitions for \(n\in \mathbb{N}\).

Definition 1.1

(see [5])

Let f be a meromorphic function in \(\mathbb{D}\). Then the iterated n-order of f is defined by

where \(\log ^{+}_{1}x=\log ^{+}x=\max \{\log x,0\}, \log ^{+}_{n+1}x={ \log ^{+}(\log ^{+}_{n}x)}\). For \(n=1\), \(\sigma _{1}(f)=\sigma (f)\).

If f is analytic in \(\mathbb{D}\), then the iterated n-order is defined by

For \(n=1\), \(\sigma _{M,1}(f)=\sigma _{M}(f)\).

Remark 1.1

(see [5, 6])

It follows by M. Tsuji that if f is an analytic function in \(\mathbb{D}\), then

which is best possible in the sense that there are analytic functions g and h such that \(\sigma _{M,1}(g)=\sigma _{1}(g)\) and \(\sigma _{M,1}(h)=\sigma _{1}(h)+1\), see [7]. However, it follows by Proposition \(2.2.2\) in [3] that \(\sigma _{M,n}(f)=\sigma _{n}(f)\) for \(n\geq 2\).

Definition 1.2

(see [5])

Let f be a meromorphic function in \(\mathbb{D}\). Then the iterated n-convergence exponent of the sequence of zeros in \(\mathbb{D}\) of \(f(z)\) is defined by

where \(N(r,\frac{1}{f})\) is the integrated counting function of zeros of \(f(z)\).

Similarly, the iterated n-convergence exponent of the sequence of distinct zeros in \(\mathbb{D}\) of \(f(z)\) is defined by

where \(\overline{N}(r,\frac{1}{f})\) is the integrated counting function of distinct zeros of \(f(z)\).

Definition 1.3

Let f be a meromorphic function in \(\mathbb{D}\). Then the iterated convergence n-exponent of the sequence of fixed points in \(\mathbb{D}\) of \(f(z)\) is defined by

and the iterated n-convergence exponent of the sequence of distinct fixed points in \(\mathbb{D}\) of \(f(z)\) is defined by

Definition 1.4

(see [8])

For a measurable set \(E\subset [0,1)\), the upper and lower densities are defined as

respectively, where \(m(F)\) is the Lebesgue measure of F.

The next Remark 1.2 follows by Sect. 7 in [8] or can be seen in [9].

Remark 1.2

(see [8, 9])

If a set E satisfies \(\overline{\mathrm{dens}}_{\mathbb{D}}E>0\), then \(\int _{E}\frac{dr}{1-r}=+\infty \).

Remark 1.3

Remark 1.2 also holds with the definitions of the upper densities in [5, 10]; therefore, the results of this paper are still valid for the definitions of the upper densities in [5, 10].

The theory of complex linear differential equations in the unit disc has been developed since 1980s. In recent years, after J. Heittokangas’ work in [4], there has been an increasing interest in studying the complex oscillation of linear differential equations in the unit disc, and many important results in the unit disc \(\mathbb{D}\) analogous to those on the complex plane \(\mathbb{C}\) have been obtained. G. G. Gundersen [11] studied the growth of solutions of one type of second-order linear differential equations on \(\mathbb{C}\) (see the following Theorem A). After that, K. H. Kwon [12], Z. X. Chen and C. C. Yang [13], B. Belaïdi [14, 15], and the first author [16], extended the type of the coefficients with less control constants, removed infinitesimals, and obtained some improved results. T. B. Cao and H. X. Yi in [10], and T. B. Cao in [5] generalized the results of [13] and [14] on \(\mathbb{C}\) to corresponding results in \(\mathbb{D}\), respectively. Later, some improvements and extensions of the type of coefficients in the unit disc were investigated (see [17, 18]) and gave rise to the unit disc analogues of the results of [14, 16].

Theorem A

(see [11])

Let \(A(z)\) and \(B(z)\not \equiv 0\) be entire functions, and let \(\alpha,\beta, \theta _{1}\) and \(\theta _{2}\) be real numbers with \(\alpha >0, \beta >0\) and \(\theta _{1}<\theta _{2}\). If

and

as \(|z|\rightarrow \infty \) with \(\theta _{1}\leq \arg z\leq \theta _{2}\), then every solution \(f\not \equiv 0\) of the equation

has infinite order.

T. B. Cao in [5] investigated the iterated order of solutions of higher-order equations and obtained the unit disc analogues of B. Belaïdi’s results in [14]. As for the equation

he obtained the following results.

Theorem B

(see [5])

Let H be a set of complex numbers satisfying \(\overline{dens}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\), and let \(A_{0},A_{1},\ldots,A_{k}\) be analytic functions in \(\mathbb{D}\) such that for some real constants \(0\leq \beta <\alpha \) and \(\mu >0\) we have

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of equation (1.1) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)\geq \mu \).

Theorem C

(see [5])

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\), and let \(A_{0},A_{1},\ldots,A_{k}\) be analytic functions in \(\mathbb{D}\) such that for some real constants \(0\leq \beta <\alpha \) and \(\mu >0\) we have

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of equation (1.1) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)\geq \mu \).

And as for the equation

T. B. Cao obtained more accurate results as follows.

Theorem D

(see [5])

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\), and let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in \(\mathbb{D}\) such that

and for some constants \(0\leq \beta <\alpha \) we have, for all \(\varepsilon >0\) sufficiently small,

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every solution \(f\not \equiv 0\) of equation (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\).

Theorem E

(see [5])

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\), and let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in \(\mathbb{D}\) such that

and for some constants \(0\leq \beta <\alpha \) we have, for all \(\varepsilon >0\) sufficiently small,

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every solution \(f\not \equiv 0\) of equation (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\alpha _{M,n}\geq \sigma _{n+1}(f)\geq \sigma _{n}(A_{0})\), where \(\alpha _{M,n}=\max \{\sigma _{M,n}(A_{j}):j=0,1,\ldots,k-1\}\).

The first aim of this paper is to extend the results of B. Belaïdi, T. B. Cao, and the authors by optimizing the conditions of coefficients with less control constants to contrast coefficients, and obtaining better estimates of the growth of the solutions. We will decrease the control constants of the coefficients’ modulus or characteristic functions to one or two constants and obtain the same results. Furthermore, we will improve the result of Theorem E to obtain more accurate estimate of the growth of solution. Note that Theorem E only gave a range of \(\sigma _{n+1}(f)\) between \(\alpha _{M,n}\) and \(\sigma _{n}(A_{0})\), while by Remark 1.1, it is best possible that \(\sigma _{M,n}(A_{0})\neq \sigma _{n}(A_{0})\) as \(n=1\). This means even if \(A_{0}\), as a dominant coefficient, satisfies \(\alpha _{M,1}=\max \{\sigma _{M}(A_{j}):j=1,2,\ldots,k-1\}=\sigma _{M}(A_{0})\) and \(\max \{\sigma (A_{i}):i=1,2,\ldots,k-1\}\leq \sigma (A_{0})\), we still cannot conclude that \(\sigma _{2}(f)\) is equal to \(\sigma (A_{0})\) or \(\sigma _{M}(A_{0})\) by Theorem E. Thus it is natural to pose the question: Can we get a precise value of \(\sigma _{n+1}(f)\) in the case of contrasting coefficients by their characteristic functions? We will solve this problem in Theorems 1.3, 1.4 and Corollary 1.1.

In addition, T. B. Cao also investigated the fixed points of homogeneous linear differential equations in \(\mathbb{D}\) and obtained the following results in [5].

Theorem F

(see [5])

Under the hypothesis of one of Theorem Dand E, if \(A_{1}(z)+zA_{0}(z)\not \equiv 0\), then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\overline{\lambda }_{n+1}(f-z)=\sigma _{n+1}(f)\).

After that, when \(A_{j}(z)\equiv 0(j=1,\ldots,k-1)\), G. W. Zhang and A. Chen [19] studied the fixed points of the i-order \((1\leq i\leq k)\) derivatives of solutions of the equation

and obtained the results as follows.

Theorem G

(see [19])

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\), and let \(A(z)\) be an analytic function in \(\mathbb{D}\) such that \(\sigma _{M,n}(A)=\sigma <\infty \), and for constant α we have, for all \(\varepsilon >0\) sufficiently small,

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Assume that f is a nontrivial solution of equation (1.3). Then

Theorem H

(see [19])

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\), and let \(A(z)\) be an analytic function in \(\mathbb{D}\) such that \(\sigma _{n}(A)=\sigma <\infty \), and for constant α we have, for all \(\varepsilon >0\) sufficiently small,

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Assume that f is a nontrivial solution of equation (1.3). Then

However, if the equation has two or more than two coefficients, there arises some difficulties to consider: whether applying the general iterative method, by substituting \(g^{(i)}=f^{(i)}-z\) into the corresponding equations (see the proof of Theorem 1.9), would result in vanishing \(A_{0,j}\) and \(F_{j}\) for any \(j\in \mathbb{N}\) (see (5.29)–(5.30)), which consequently would result in interruption of the iteration. Yet we have not seen any valid result on the fixed points of arbitrary-order derivatives of solutions of higher-order equation (1.2) in the unit disc for this. A similar problem has been found recently in an iterative process related to the solutions’ arbitrary-order derivatives, where the corresponding items generated by iteration were supposed not to vanish identically (see, e.g., [20, 21]). Thus a natural question is: how to judge these possible vanishing items and whether the iteration can be carried out all the time.

The second aim of this paper is to investigate the fixed points of solutions and their arbitrary-order derivatives of general higher order equations (1.1) and (1.2). We tackle the above problem concisely, extend Theorems G and H to more general equation, and further improve them by obtaining precise estimates of the fixed points of arbitrary-order derivatives of solutions. At the same time, we improve Theorem F by removing the condition \(A_{1}(z)+zA_{0}(z)\not \equiv 0\).

Theorem 1.1

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that \(\max \{\sigma _{M,n}(A_{i}):i=1,2,\ldots,k-1\}\leq \sigma _{M,n}(A_{0})= \mu (0<\mu <\infty )\), and for a constant \(\alpha \geq 0\), we have

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\).

Theorem 1.2

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that \(\max \{\sigma _{M,n}(A_{i}):i=1,2,\ldots,k-1\}\leq \sigma _{M,n}(A_{0})= \mu (0<\mu <\infty )\) and

Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\).

Theorem 1.3

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that \(\max \{\sigma _{M,n}(A_{i}):i=1,2,\ldots,k-1\}\leq \sigma _{M,n}(A_{0})= \mu (0<\mu <\infty )\), and for a constant \(\alpha \geq 0\), we have

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\).

Theorem 1.4

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that \(\max \{\sigma _{M,n}(A_{i}):i=1,2,\ldots,k-1\}\leq \sigma _{M,n}(A_{0})= \mu (0<\mu <\infty )\) and

Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\).

By taking upper and lower limits after some identical transformations of inequalities, one can easily obtain the following corollary from Theorem 1.3 or Theorem 1.4.

Corollary 1.1

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that \(\max \{\sigma _{M,n}(A_{i}):i=1,2,\ldots,k-1\}\leq \sigma _{M,n}(A_{0})= \mu (0<\mu <\infty )\), and for some constants \(0\leq \beta <\alpha \), we have

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\).

Remark 1.4

Since for any given ε \((0<\varepsilon <\mu )\) we can substitute μ by \(\mu -\varepsilon \) in the proofs of Theorem 1.1 to Theorem 1.4 and ε is arbitrary, Theorem D is generalized to Theorem 1.1 and Theorem 1.2, and Theorem E to Theorem 1.3 and Theorem 1.4 with less control constants of coefficient conditions. Particularly, Theorem 1.3, Theorem 1.4 and Corollary 1.1 improve Theorem E further by providing a precise value of \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})\) instead of a range \(\alpha _{M,n}\geq \sigma _{n+1}(f)\geq \sigma _{n}(A_{0})\).

For equation (1.1), we also generalize Theorem B to Theorem 1.5 and Theorem 1.6, Theorem C to Theorem 1.7 and Theorem 1.8 as follows.

Theorem 1.5

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k}\) be analytic functions in the unit disc \(\mathbb{D}\), and for some constants \(\alpha \geq 0\) and \(\mu >0\), we have (1.4) and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of (1.1) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)\geq \mu \).

Theorem 1.6

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k}\) be analytic functions in the unit disc \(\mathbb{D}\), and for a constant \(\mu >0\), we have

Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of (1.1) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)\geq \mu \).

Theorem 1.7

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k}\) be analytic functions in the unit disc \(\mathbb{D}\), and for some constants \(\alpha \geq 0\) and \(\mu >0\), we have (1.7) and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of (1.1) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)\geq \mu \).

Theorem 1.8

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k}\) be analytic functions in the unit disc \(\mathbb{D}\), and for a constant \(\mu >0\), we have

Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of (1.1) satisfies \(\sigma _{n}(f)=\infty \) and \(\sigma _{n+1}(f)\geq \mu \).

When \(A_{k}(z)\equiv 1\), for any given ε \((0<\varepsilon <\mu )\), by substituting μ with \(\mu -\varepsilon \) in the proofs of Theorem 1.7, Theorem 1.8 and combining with Lemma 2.4, we obtain the extensions of Theorem E in the following corollaries. And of course, the corollaries still hold if we substitute \(\mu -\varepsilon \) with μ in them.

Corollary 1.2

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that

and for a constant \(\alpha \geq 0\) and all \(\varepsilon >0\) sufficiently small, we have

and

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\alpha _{M,n}\geq \sigma _{n+1}(f)\geq \sigma _{n}(A_{0})\), where \(\alpha _{M,n}=\max \{\sigma _{M,n}(A_{j}):j=0,1,\ldots,k-1\}\).

Corollary 1.3

Let H be a set of complex numbers satisfying \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\). Let \(A_{0},A_{1},\ldots,A_{k-1}\) be analytic functions in the unit disc \(\mathbb{D}\) such that

and for all \(\varepsilon >0\) sufficiently small, we have

Then every solution \(f\not \equiv 0\) of (1.2) satisfies \(\sigma _{n}(f)=\infty \) and \(\alpha _{M,n}\geq \sigma _{n+1}(f)\geq \sigma _{n}(A_{0})\), where \(\alpha _{M,n}=\max \{\sigma _{M,n}(A_{j}):j=0,1,\ldots,k-1\}\).

Moreover, we obtain some results of the fixed points of solutions and their arbitrary-order derivatives of general high-order linear differential equations (1.1) and (1.2) as follows.

Theorem 1.9

Assume that the assumptions of Theorem 1.1or Theorem 1.2hold. Then every solution \(f\not \equiv 0\) of (1.2) satisfies

Theorem 1.10

Assume that the assumptions of one of Theorem 1.3, Theorem 1.4and Corollary 1.1hold. Then every solution \(f\not \equiv 0\) of (1.2) satisfies

Theorem 1.11

Assume that the assumptions of one of Theorem 1.5to Theorem 1.8hold. Then every meromorphic (or analytic) solution \(f\not \equiv 0\) of (1.1) satisfies

Set \(A_{k}(z)\equiv 1\). Then it is easy to know Corollary 1.4 follows by Theorem 1.11.

Corollary 1.4

Assume that the assumptions of Corollary 1.2or Corollary 1.3hold. Then every solution \(f\not \equiv 0\) of (1.2) satisfies

Remark 1.5

Obviously, Theorems F, G, and H are direct results of Theorem 1.9 to Theorem 1.11 and Corollary 1.4, which significantly improve the formers.

Remark 1.6

It is easy to know from the proofs that for any given ε \((0<\varepsilon <\mu )\) all these results still hold if we substitute μ in (1.4)–(1.9) by \(\mu -\varepsilon \). By taking both sides of inequalities upper or lower limits after some identical transformations, we can easily conclude that the conditions in the above results contain the corresponding conditions in Theorems B, C, D, and E, so these results extend those in [5] and [19].

Lemma 2.1

(see [7])

Let k and j be integers satisfying \(k>j\geq 0\), and let \(\varepsilon >0\) and \(d\in (0,1)\). If f is meromorphic in \(\mathbb{D}\) such that \(f^{(j)}\) does not vanish identically, then

where \(E\subset [0,1)\) with finite logarithmic measure \(\int _{E}\frac{dr}{1-r}<\infty \) and \(s(|z|)=1-d(1-|z|)\). Moreover, if \(\sigma _{1}(f)<\infty \), then

while if \(\sigma _{n}(f)<\infty \) for \(n\geq 2\), then

Lemma 2.2

(see [22])

Let \(g:(0,1)\rightarrow \mathbb{R}\) and \(h:(0,1)\rightarrow \mathbb{R}\) be monotone increasing functions such that \(g(r)\leq h(r)\) holds outside of an exceptional set \(E\subset [0,1)\) for which \(\int _{E}\frac{ {dr}}{1-r}<\infty \). Then there exists a constant \(d\in (0,1)\) such that if \(s(r)=1-d(1-r)\), then \(g(r)\leq h(s(r))\) for all \(r\in [0,1)\).

Lemma 2.3

(see [23])

Let f be a solution of (1.2) where the coefficients \(A_{j}(z)(j=0,\ldots,k-1)\) are analytic functions in the disc \(D_{R}=\{z\in \mathbb{C}:|z|< R\}\), \(0< R\leq \infty \), let \(n_{c}\in \{1,\ldots,k\}\) be the number of nonzero coefficients \(A_{j}(z),j=0,\ldots,k-1\), and let \(\theta \in [0,2\pi )\) and \(\varepsilon >0\). If \(z_{\theta }=\nu e^{i\theta }\in D_{R}\) is such that \(A_{j}(z_{\theta })\neq 0\) for some \(j=0,\ldots,k-1\), then for all \(\nu < r< R\),

where \(C>0\) is a constant satisfying

The next lemma follows by Lemma 2.3.

Lemma 2.4

Let \(n\in \mathbb{N}\). If the coefficients \(A_{0}(z),A_{1}(z),\ldots,A_{k-1}(z)\) are analytic in \(\mathbb{D}\), then all solutions of (1.2) satisfy \(\sigma _{M,n+1}(f)\leq \max \{\sigma _{M,n}(A_{j}):j=0,\ldots,k-1\}\).

Lemma 2.5

(see [4])

Let f be a meromorphic function in the unit disc, and let \(k\geq 1\) be an integer. Then

where \(S(r,f)=\mathit{O}(\log ^{+}T(r,f)+\log (\frac{1}{1-r}))\), possibly outside a set \(E\subset [0,1)\) with \(\int _{E}\frac{ {dr}}{1-r}<+\infty \). If f is of finite order of growth, then

Lemma 2.6

(see [24])

If f and g are meromorphic functions in \(\mathbb{D}\), \(n\in \mathbb{N}\), then we have

1. (i)

   \(\sigma _{n}(f)=\sigma _{n}(1/f), \sigma _{n}(a\cdot f)=\sigma _{n}(f)(a \in \mathbb{C}-\{0\})\);

2. (ii)

   \(\sigma _{n}(f)=\sigma _{n}(f')\);

3. (iii)

   \(\max \{\sigma _{n}(f+g),\sigma _{n}(f\cdot g)\}\leq \max \{\sigma _{n}(f), \sigma _{n}(g)\}\);

4. (iv)

   if \(\sigma _{n}(f)<\sigma _{n}(g)\), then \(\sigma _{n}(f+g)=\sigma _{n}(g), \sigma _{n}(f\cdot g)=\sigma _{n}(g)\).

Lemma 2.7

(see [25])

Let \(A_{0},A_{1},\ldots,A_{k-1}\) and \(F\not \equiv 0\) be meromorphic functions in \(\mathbb{D}\), and let f be a meromorphic solution of the differential equation

such that

Then \(\overline{\lambda }_{p}(f)=\lambda _{p}(f)=\sigma _{p}(f)\).

Using the same arguments as in the proof of Lemma 2.7 (see [25]), we easily obtain the following lemma.

Lemma 2.8

Let \(A_{0},A_{1},\ldots,A_{k-1}\) and \(F(\not \equiv 0)\) be finite iterated p-order meromorphic functions in \(\mathbb{D}\). If f is a meromorphic solution with \(\sigma _{p}(f)=\infty \) and \(\sigma _{p+1}(f)=\rho <\infty \) of equation (2.1), then \(\overline{\lambda }_{p}(f)=\lambda _{p}(f)=\sigma _{p}(f)=\infty \) and \(\overline{\lambda }_{p+1}(f)=\lambda _{p+1}(f)=\sigma _{p+1}(f)=\rho \).

Lemma 2.9

(see [26])

Let \(A_{0},A_{1},\ldots,A_{k-1}\) and \(F(\not \equiv 0)\) be finite iterated p-order analytic functions in \(\mathbb{D}\). If f is a solution with \(\sigma _{p}(f)=\infty \) and \(\sigma _{p+1}(f)=\rho <\infty \) of the equation

then \(\overline{\lambda }_{p}(f)=\lambda _{p}(f)=\sigma _{p}(f)=\infty \) and \(\overline{\lambda }_{p+1}(f)=\lambda _{p+1}(f)=\sigma _{p+1}(f)=\rho \).

Proof of Theorem 1.1

Suppose that \(f\not \equiv 0\) is a solution of equation (1.2). From (1.2), we get

By the assumption of Theorem 1.1, there is a set H of complex numbers with \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\) satisfying (1.4) and (1.5) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). By (1.4), we know that there exists a real number γ such that

It is easy to know that

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). By (1.5) and (3.2), we obtain

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). By Lemma 2.1, there exists a set \(E_{1}\subset [0,1)\) with \(\int _{ E_{1}}\frac{ {dr}}{1-r}<\infty \) such that, for all \(z\in \mathbb{D}\) satisfying \(|z|\notin E_{1}\) and \(i=1,2,\ldots,k\), we have

where \(s(|z|)=1-d(1-|z|)\) and \(d\in (0,1)\). Applying (3.3) and (3.4) to (3.1), we obtain

as \(|z|\rightarrow 1^{-}\) for \(z\in H\) and \(|z|\notin E_{1}\). It follows that

as \(|z|\rightarrow 1^{-}\) for \(z\in H\) and \(|z|\notin E_{1}\). Obviously, \(\int _{\{|z|:z\in H\}\setminus E_{1}}\frac{ {dr}}{1-r}=\infty \). Hence, by (3.5) and combining with Lemma 2.2, we can easily obtain \(\sigma _{n}(f)=\infty \) and

By Lemma 2.4, we deduce that

Therefore, we obtain \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})=\mu \). □

Proof of Theorem 1.2

Set

By (1.6), there exist real numbers \(\alpha,\gamma \) such that \(\alpha _{i}<\alpha <\gamma <\gamma _{0},i=1,2,\ldots,k-1\). It yields

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Hence, we have (3.3) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Using the same proof as in Theorem 1.1, we can get the conclusion of Theorem 1.2. □

Proof of Theorem 1.3

Suppose that \(f\not \equiv 0\) is a solution of equation (1.2). From (1.2), we get

It follows that

From the assumption of Theorem 1.3, there exists a set H of complex numbers with \(\overline{\mathrm{dens}}_{\mathbb{D}}\{|z|:z\in H\subseteq \mathbb{D}\}>0\) satisfying (1.7) and (1.8) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). By (1.7), we know that there exists a real number γ such that

It is easy to know that

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). By (1.8) and (3.7), we obtain

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). With (3.6), (3.8), and Lemma 2.5, using a similar proof as in Theorem 1.3 of [5], we can easily obtain \(\sigma _{n}(f)=\infty \) and

By Lemma 2.4, we obtain \(\sigma _{n+1}(f)\leq \sigma _{M,n}(A_{0})=\mu \). Therefore, \(\sigma _{n+1}(f)=\sigma _{M,n}(A_{0})=\mu \). We complete the proof. □

Proof of Theorem 1.4

Set

By (1.9), there exist real numbers \(\alpha,\gamma \) such that \(\alpha _{i}<\alpha <\gamma <\gamma _{0},i=1,2,\ldots,k-1\). It yields that

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Hence, we have (3.8) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Using the same proof as in Theorem 1.3, we can get the conclusion of Theorem 1.4. □

Proofs of Theorems 1.5 and 1.6

Using a similar discussion as in the proof of Theorem 1.1 or Theorem 1.2, we know that there exists a real number \(\gamma >\alpha \) such that

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Combining Theorem B with (4.1), we have the conclusion. □

Proofs of Theorems 1.7 and 1.8

Using a similar discussion as in the proof of Theorem 1.3 or Theorem 1.4, we know that there exists a real number \(\gamma >\alpha \) such that

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). Combining Theorem C with (4.2), we have the conclusion. □

Proof of Theorem 1.9

Suppose that \(f\not \equiv 0\) is a solution of equation (1.2). By Theorem 1.1 or Theorem 1.2, we have

Step 1. We consider the fixed points of \(f(z)\). Set \(g(z)=f(z)-z, z\in \mathbb{D}\). Then, by (5.1), we get

Substituting \(f=g+z\) into (1.2), we get

Next we prove that \(-A_{1}-zA_{0}\not \equiv 0\). Suppose that \(-A_{1}-zA_{0}\equiv 0\). Obviously, \(A_{0}\not \equiv 0\). Then \(\frac{A_{1}}{A_{0}}=-z\). Thus we have \(|\frac{A_{1}}{A_{0}}|\rightarrow 1\) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). While by (3.3), we have

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). (5.4) yields \(|\frac{A_{1}}{A_{0}}|\rightarrow 0\) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). This is a contradiction. Hence, \(-A_{1}-zA_{0}\not \equiv 0\). By Lemma 2.6, we have

Hence, we deduce by (5.2), (5.3) and Lemma 2.9 that \(\overline{\lambda }_{n}(g)=\sigma _{n}(g)=\infty \), \(\overline{\lambda }_{n+1}(g)=\sigma _{n+1}(g)=\mu \). Therefore, we obtain

Step 2. We consider the fixed points of \(f^{(j)}(z)(j=1,2,\ldots)\). For the proof, we use the principle of mathematical induction. Set \(A_{k}(z)=1\). Then \(|{A_{k}(z)}|\leq \exp _{n}\{\alpha (\frac{1}{1-|z|})^{\mu }\}\) and equation (1.2) becomes (1.1). Set \(g_{1}(z)=f'(z)-z, z\in \mathbb{D}\). Then, by (5.1), we get

Dividing both sides of (1.1) by \(A_{0}\), we obtain

Differentiating both sides of equation (5.6), we have

Multiplying now (5.7) by \(A_{0}\), we get

Substituting \(f'=g_{1}+z\) into (5.8), we get

where

Now we prove that \(A_{0,1}\not \equiv 0\). Suppose that \(A_{0,1}\equiv 0\). By \(A_{0}\not \equiv 0\), we get \((\frac{A_{1}}{A_{0}})'+1\equiv 0\), and then \(\frac{A_{1}}{A_{0}}=-z+C_{0}\), where \(C_{0}\) is an arbitrary constant. Thus, we have \(A_{1}+(z-C_{0})A_{0}=0\). Then, by (1.2), we know that \(f_{0}=z-C_{0}\) is a solution of equation (1.2) and \(\sigma _{n}(f_{0})<\infty \). This contradicts (5.1). Hence \(A_{0,1}\not \equiv 0\). Now we prove \(F_{1}\not \equiv 0\). Suppose that \(F_{1}\equiv 0\). By (5.12),

If \(f'=z\), then by (5.8) and (5.12) we know that f is a solution of (5.8). Hence equation (1.2) has a solution \(f_{1}\) satisfying \(f_{1}'=z\) and \(\sigma _{n}(f_{1})<\infty \). This contradicts (5.1). Hence \(F_{1}\not \equiv 0\). By (5.10)–(5.12) and Lemma 2.6, we have

Hence, by (5.5), (5.9) and using Lemma 2.8 or Lemma 2.9, we have \(\overline{\lambda }_{n}(g_{1})=\sigma _{n}(g_{1})=\infty, \overline{\lambda }_{n+1}(g_{1})=\sigma _{n+1}(g_{1})=\mu \). Therefore, we obtain

Set \(g_{2}(z)=f''(z)-z, z\in \mathbb{D}\). Then, by (5.1), we get

Dividing both sides of (5.8) by \(A_{0,1}\), we obtain

Differentiating both sides of equation (5.15), we have

Multiplying now (5.16) by \(A_{0,1}\), we get

Substituting \(f''=g_{2}+z\) into (5.17), we get

where

Now we prove that \(A_{0,2}\not \equiv 0\). Suppose that \(A_{0,2}\equiv 0\). By \(A_{0,1}\not \equiv 0\), we get \((\frac{A_{1,1}}{A_{0,1}})'+1\equiv 0\), and then \(\frac{A_{1,1}}{A_{0,1}}=-z+C\), where C is an arbitrary constant. Thus, we have

If \(f'=z-C\), then by (5.8) and (5.22) we know that f is a solution of (5.8). Hence equation (1.2) has a solution \(f_{1,2}\) satisfying \(f_{1,2}'=z-C\) and \(\sigma _{n}(f_{1,2})<\infty \). This contradicts (5.1). Hence \(A_{0,2}\not \equiv 0\). Next we prove \(F_{2}\not \equiv 0\). Suppose that \(F_{2}\equiv 0\). By (5.21),

If \(f''=z\), then by (5.17) and (5.23) we know that f is a solution of (5.17). Hence equation (1.2) has a solution \(f_{2}\) satisfying \(f_{2}''=z\) and \(\sigma _{n}(f_{2})<\infty \). This contradicts (5.1). Hence \(F_{2}\not \equiv 0\). By (5.19)–(5.21) and Lemma 2.6, we have

Hence, we deduce by (5.14), (5.18), and Lemma 2.8 or Lemma 2.9 that \(\overline{\lambda }_{n}(g_{2})=\sigma _{n}(g_{2})=\infty, \overline{\lambda }_{n+1}(g_{2})=\sigma _{n+1}(g_{2})=\mu \). Therefore, we obtain

Suppose now that

for all \(s=0,1,\ldots,j-1\), and we prove that (5.24) is true for \(s=j\). Set \(g_{j}(z)=f^{(j)}(z)-z, z\in \mathbb{D}\). Then, by (5.1), we get

By the same procedure as before, we can obtain

and

where

satisfying \(A_{0,j}\not \equiv 0, F_{j}\not \equiv 0\). By using Lemma 2.8 or Lemma 2.9 in (5.27), we have

Then, by (5.25) and (5.31), we obtain

It follows that

The proof is complete. □

Proof of Theorem 1.10

Suppose that \(f\not \equiv 0\) is a solution of equation (1.2). By Theorem 1.3 or Theorem 1.4, we have (5.1). Now we prove that \(-A_{1}-zA_{0}\not \equiv 0\). Suppose that \(-A_{1}-zA_{0}\equiv 0\). It yields \(A_{1}=-zA_{0}\) and \(A_{0}=\frac{A_{1}}{-z}\). Hence

By (5.32), we obtain

Using the same discussion as in the proof of Theorem 1.3, we have

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). It follows that

and for \(n=1\),

and for \(n\geq 2\),

as \(|z|\rightarrow 1^{-}\) for \(z\in H\). By (5.33) and (5.34), we have \(\frac{T(r,A_{1})}{T(r,A_{0})}\rightarrow 1\) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). But, by (5.35) and (5.36), we can get \(\frac{T(r,A_{1})}{T(r,A_{0})}\nrightarrow 1\) as \(|z|\rightarrow 1^{-}\) for \(z\in H\). This is a contradiction. Therefore, \(-A_{1}-zA_{0}\not \equiv 0\). Set \(A_{k}(z)=1\). Then \(T(r,A_{k})\leq \exp _{n-1}\{\alpha (\frac{1}{1-|z|})^{\mu }\}\). Obviously, \(A_{0}\not \equiv 0\). Arguing the same as in the proof of Theorem 1.9, we can complete the proof. □

Proof of Theorem 1.11

For any \(A_{k}(z)\), using the same reasoning in the proofs of Theorem 1.9 and Theorem 1.10 and replacing \(\sigma _{n+1}(f)=\mu \) with \(\sigma _{n+1}(f)\geq \mu \), \(\sigma _{n+1}(f^{(j)})=\mu (j=1,2,\ldots,k)\) with \(\sigma _{n+1}(f^{(j)})\geq \mu (j=1,2,\ldots,k)\), we can complete the proof of Theorem 1.11. □

Data sharing not applicable to this article as no data sets were generated or analyzed during the current study.

The authors would like to thank the editor and referees for their valuable and helpful comments and suggestions that improved the quality of the paper.

This work was supported by the National Natural Science Foundation of China (11971042 and 11561031) and Beijing Natural Science Foundation in China (1182008).

Authors and Affiliations

1. School of Mathematical Sciences, Laboratory of Mathematics and Complex Systems of Ministry of Education, Beijing Normal University, Beijing, China

   Yu Chen, Guan-Tie Deng & Wei-Wei Wang

2. School of Mathematics and Statistics, Jiangxi Normal University, Nanchang, China

   Yu Chen

3. Mathematics teaching and Research Office, The Experiimental Er Long Lu Middle School Attached to Beijing Normal University, Beijing, China

   Zhan-Mei Chen

Contributions

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

Corresponding author

Correspondence to Yu Chen.

Competing interests

The authors declare that they have no competing interests.

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