Differential inequalities for spirallike and strongly starlike functions

In this paper, by using a technique of the first-order differential subordination, we find several sufficient conditions for an analytic function p such that \(p(0)=1\) to satisfy \(\operatorname{Re}\{ {\mathrm{e}}^{{\mathrm{i}}\beta } p(z) \} > \gamma \) or \(| \arg \{p(z)-\gamma \} |<\delta \) for all \(z\in \mathbb{D}\), where \(\beta \in (-\pi /2,\pi /2)\), \(\gamma \in [0,\cos \beta )\), \(\delta \in (0,1]\) and \(\mathbb{D}:=\{z\in \mathbb{C}:|z|<1 \}\). The results obtained here will be applied to find some conditions for spirallike functions and strongly starlike functions in \(\mathbb{D}\).

For real numbers β, γ, and δ satisfying \(-\pi /2 < \beta <\pi /2\), \(0 \leq \gamma < \cos \beta \), and \(0 < \delta \leq 1\), define two domains \(\Omega _{\gamma }(\beta )\) and \(\Lambda _{\gamma }(\delta )\) in \(\mathbb{C}\) by

and

respectively. Then it clearly holds that

Let \(\mathbb{D}:=\{ z\in \mathbb{C}: |z|<1 \}\) be the open unit disk. Let \({\mathcal{H}}\) be the class of analytic functions in \(\mathbb{D}\), and let \({\mathcal{H}}_{1}\) be the class of functions \(p \in {\mathcal{H}}\) with \(p(0)=1\). We introduce two subfamilies \({\mathcal{P}}_{\gamma }(\beta )\) and \({\mathcal{Q}}_{\gamma }(\delta )\) of \({\mathcal{H}}_{1}\) defined as follows:

and

A function p in \({\mathcal{P}}_{\gamma }(0)\) is said to be a Carathéodory function of order γ in \(\mathbb{D}\). In particular, \({\mathcal{P}}_{0}(0) \equiv {\mathcal{P}}\) is the well-known class of Carathéodory functions. Also, a function p in \({\mathcal{P}}_{0}(\beta )\) is said to be a tilted Carathéodory function by angle β [27]. We note that

holds, by (1.1).

Let \({\mathcal{A}}\) denote the class of functions f in \({\mathcal{H}}\) normalized by \(f(0)=0=f'(0)-1\). And let \({\mathcal{S}}\) be the subclass of \({\mathcal{A}}\) consisting of all univalent functions. Further we denote by \({\mathcal{S}}_{\gamma }^{*}(\beta )\) and \({\mathcal{SS}}_{\gamma }^{*}(\delta )\) the subclass of \({\mathcal{A}}\) consisting of β-spirallike functions of order γ [8, II, p. 89] (see also [16, 24]) and strongly starlike functions of order δ and type γ [9]. That is, a function \(f \in {\mathcal{A}}\) belongs to the class \({\mathcal{S}}_{\gamma }^{*}(\beta )\) if f satisfies

and belongs to the class \({\mathcal{SS}}_{\gamma }^{*}(\delta )\) when f satisfies

Thus we have

and

where \(J_{f}(z):=zf'(z)/f(z)\), \(z\in \mathbb{D}\). Note that \({\mathcal{S}}_{\gamma }^{*}(0) \equiv {\mathcal{S}}^{*}(\gamma )\) is the class of starlike functions of order γ, and \({\mathcal{S}}_{0}^{*}(\beta ) \equiv {\mathcal{SP}}(\beta )\) is the class of β-spirallike functions. It is well known [24] (or [8, Vol. I, p. 149]) that \({\mathcal{S}}^{*}(\gamma )\) and \({\mathcal{SP}}(\beta )\) are the subclasses of \({\mathcal{S}}\). See [7, 12, 28] for sufficient conditions for spirallike functions. We also note that \({\mathcal{SS}}_{\gamma }^{*}(\delta ) \subset {\mathcal{S}}_{\gamma }^{*}(0) \subset {\mathcal{S}}\). Especially, \({\mathcal{SS}}_{0}^{*}(\delta ) \equiv {\mathcal{SS}}^{*}(\delta )\) which is the class of strongly starlike functions of order δ [4, 25]. Refer to [5, 6, 11, 13, 14, 17–20, 23, 26] for various sufficient conditions for strongly starlike functions.

In the present paper we investigate new sufficient conditions for functions in \({\mathcal{P}}_{\gamma }(\beta )\) or \({\mathcal{Q}}_{\gamma }(\delta )\). As direct consequences of these results, we will obtain several sufficient conditions for spirallike functions or strongly starlike functions in \(\mathbb{D}\).

For analytic functions f and g, we say that f is subordinate to g, denoted by \(f\prec g\), if there is an analytic function \(\omega :\mathbb{D}\rightarrow \mathbb{D}\) with \(|\omega (z)|\leq |z|\) such that \(f(z)=g(\omega (z))\). Further, if g is univalent, then the definition of subordination \(f\prec g\) simplifies to the conditions \(f(0)=g(0)\) and \(f(\mathbb{D})\subseteq g(\mathbb{D})\) (see [21, p. 36]).

Let \(\overline{\mathbb{D}}=\{ z\in \mathbb{C}: |z| \leq 1 \}\) and \(\partial \mathbb{D}=\{ z\in \mathbb{C}: |z| = 1 \}\) be the closure and boundary of \(\mathbb{D}\), respectively. We denote by \({\mathcal{R}}\) the class of functions q that are analytic and injective on \(\overline{\mathbb{D}}\setminus E(q)\), where

and are such that

Furthermore, let the subclass of \({\mathcal{R}}\) for which \(q(0)=a\) be denoted by \({\mathcal{R}}(a)\). We recall the following lemma which will be used for our results.

Lemma 1.1

([15, p. 24])

Let \(q \in {\mathcal{R}}(a)\) and let

be an analytic function in \(\mathbb{D}\) with \(p(0) = a\). If p is not subordinate to q, then there exist points \(z_{0} \in \mathbb{D}\) and \(\zeta _{0} \in \partial \mathbb{D} \setminus E(q)\) for which

1. (i)

   \(p(z_{0}) = q(\zeta _{0})\);

2. (ii)

   \(z_{0}p'(z_{0}) = m\zeta _{0}q'(\zeta _{0})\) \((m\geq n\geq 1)\).

Throughout this section, let β and γ be real numbers such that \(-\pi /2 < \beta < \pi /2\) and \(0 \leq \gamma < \cos \beta \) unless we mention it. We define a function \(\varphi _{\beta ,\gamma } :\mathbb{D} \rightarrow \mathbb{C}\) by

Then it is easy to check that the bilinear function \(\varphi _{\beta ,\gamma }\) maps the unit disk \(\mathbb{D}\) onto the half-plane \(\Omega _{\gamma }(\beta )\). By using the function \(\varphi _{\beta ,\gamma }\) we obtain the following results.

Theorem 2.1

Let \(\alpha \in \mathbb{C}\) with \(\operatorname{Re}(\alpha ) \geq 0\). If \(p \in {\mathcal{H}}_{1}\) satisfies

then \(1/p \in {\mathcal{P}}_{\gamma }(-\beta )\). That is, \(\operatorname{Re}\{ {\mathrm{{e}}}^{{\mathrm{{i}}}\beta }/p(z) \} > \gamma \) for all \(z\in \mathbb{D}\).

Proof

Let us define functions q and \(h:\mathbb{D}\rightarrow \mathbb{C}\) by

and

where \(\varphi _{\beta ,\gamma }\) is the function defined by (2.1). Then the functions q and h are analytic in \(\mathbb{D}\) with

Suppose now that q is not subordinate to h. Then, by Lemma 1.1, there exist points \(z_{0}\in \mathbb{D}\) and \(\zeta _{0} \in \partial \mathbb{D} \setminus \{ 1 \} \) such that

where

Since \(\gamma < \cos \beta \), we get \(\sigma <0\). Indeed, we have

which implies that

Using (2.3) and (2.5), we have

Let \(\alpha =\alpha _{1}+{\mathrm{{i}}}\alpha _{2}\) with \(\alpha _{1} \geq 0\) and \(\alpha _{2}\in \mathbb{R}\). Then we have

where

Furthermore it is easy to see that

Since \(m \geq 1\), from (2.8), we have

Since \(\sigma <0\), \(\alpha _{1}\geq 0\), and \(\cos \beta >\gamma \), inequality (2.9) implies

Furthermore, since \(\sigma \leq -(\cos \beta -\gamma )/2\), we have

Finally, from (2.7), (2.10), and (2.11), we obtain

This inequality contradicts hypothesis (2.2). Therefore, we obtain \(q \prec h\) in \(\mathbb{D}\) and the inequality \(\operatorname{Re}\{ {\mathrm{{e}}}^{{\mathrm{{i}}}\beta }/p(z) \} > \gamma \) holds for all \(z\in \mathbb{D}\). □

We remark that the hypothesis in Theorem 2.1 implies also \(1/p \in {\mathcal{P}}_{\gamma }(\beta )\). And we also remark that Theorem 2.1 reduces the result [13] when \(\alpha =1\).

By the above remark, taking \(\gamma =1/2\) in Theorem 2.1 gives the following corollary.

Corollary 2.1

Let α and \(\beta \in \mathbb{R}\) with \(\alpha \geq 0\) and \(\beta \in [0,\pi /3)\). If \(p \in {\mathcal{H}}_{1}\) satisfies (2.2) with \(\gamma =1/2\), then \(p(\mathbb{D}) \subset \Xi _{\beta }\), where

and we have \(\operatorname{Re}\{ p(z) \} > 0\) for all \(z\in \mathbb{D}\). Furthermore, if \(\beta \neq0\), then \(|\arg \{ p(z) \}| < \cot \beta \) for all \(z\in \mathbb{D}\).

Taking \(p(z)=zf'(z)/f(z)\), \(f\in {\mathcal{A}}\), in Corollary 2.1 gives the following result.

Corollary 2.2

Let \(\alpha \in \mathbb{R}\) with \(\alpha \geq 0\). If \(\beta \in (0,\pi /3)\) and \(f\in {\mathcal{A}}\) satisfies

then \(f \in {\mathcal{SS}}_{0}^{*}(\cot \beta )\), i.e., f is strongly starlike of order \(2(\cot \beta )/\pi \) in \(\mathbb{D}\). If \(f\in {\mathcal{A}}\) satisfies (2.12) with \(\beta =0\), then \(f \in {\mathcal{S}}_{0}^{*}(0)\), i.e., f is a starlike function in \(\mathbb{D}\).

Example 2.1

Let \(a\in \mathbb{C}\) be given, and let \(f_{a}(z)=z/(1-az)\), \(z\in \mathbb{D}\). Then a computation shows that

Hence if

then inequality (2.12) with \(\alpha =1/2\) holds. Thus, by Corollary 2.2 with \(\alpha =1/2\), we conclude that \(f_{a}\) is strongly starlike of order \(2(\cot \beta )/\pi \) in \(\mathbb{D}\) provided inequality (2.13) holds.

Example 2.2

Let \(g_{a}(z)=z/(1-az)^{2}\), \(z\in \mathbb{D}\), with \(a\in \mathbb{C}\). Then a similar computation with Example 2.1 and Corollary 2.2 gives that if \(a\in \mathbb{C}\) satisfies

then \(g_{a}\) is strongly starlike of order \(2(\cot \beta )/\pi \) in \(\mathbb{D}\).

Theorem 2.2

Let \(\alpha \in \mathbb{R}\) with \(\alpha \geq 0\). Assume that

where

with

Let \(p \in {\mathcal{H}}_{1}\) with \(\gamma {\mathrm{{e}}}^{-{\mathrm{{i}}}\beta } \notin p(\mathbb{D})\). If

then \(p \in {\mathcal{P}}_{\gamma }(-\beta )\). That is, \(\operatorname{Re}\{ {\mathrm{{e}}}^{{\mathrm{{i}}}\beta }p(z) \} > \gamma \) for all \(z\in \mathbb{D}\).

Proof

We first note that, since \(p(0)=1\), (2.14) implies that inequality (2.16) is well-defined. Next we define functions q and h by

and (2.4), respectively. If q is not subordinate to h, then there exist points \(z_{0} \in \mathbb{D}\) and \(\zeta _{0} \in \partial \mathbb{D} \setminus \{ 1 \}\) satisfying (2.5) with \(\rho \in \mathbb{R}\). We note that \(\rho \neq0\). Indeed, if \(\rho =0\), then \({\mathrm{{e}}}^{{\mathrm{{i}}}\beta }p(z_{0}) = q(z_{0}) = \gamma \). Therefore we have \(p(z_{0}) = \gamma {\mathrm{{e}}}^{-{\mathrm{{i}}}\beta }\), which contradicts the condition \(\gamma {\mathrm{{e}}}^{-{\mathrm{{i}}}\beta } \notin p(\mathbb{D})\).

Simple computations give

where σ is given by (2.6). Therefore we get

Assume that \(\rho >0\), and put

Note that

and

Since \(\rho >0\), these inequalities yield that

Therefore, since \(m \geq 1\) and \(\lambda \geq 0\), from (2.18), we obtain

where Δ is given by (2.15). This contradicts condition (2.16).

Now assume that \(\rho <0\). From (2.18), we have

where \(\tilde{\rho } = -\rho >0\). A similar calculation with (2.19) gives us to get

where Δ is given by (2.15). This also contradicts condition (2.16). Therefore we get \(q \prec h\) in \(\mathbb{D}\), and the inequality \(\operatorname{Re}\{ {\mathrm{{e}}}^{{\mathrm{{i}}}\beta }p(z) \} > \gamma \), \(z\in \mathbb{D}\), follows. □

We remark that Theorem 2.2 reduces the result [13] when \(\alpha =1\).

Theorem 2.3

Let \(\alpha \in \mathbb{C}\) with \(\operatorname{Re}(\alpha ) \geq 0\). Assume that \(\Psi (\alpha ,\beta ,\gamma ) < \cos \beta \), where

with

If \(p \in {\mathcal{H}}_{1}\) satisfies

then \(\operatorname{Re}\{ {\mathrm{{e}}}^{{\mathrm{{i}}}\beta }p(z) \} > \gamma \) for all \(z\in \mathbb{D}\).

Proof

We first note that, since \(p(0)=1\), the hypothesis \(\Psi (\alpha ,\beta ,\gamma ) < \cos \beta \) implies that inequality (2.21) is well defined. Now we define the functions q and h by (2.17) and (2.4), respectively. If q is not subordinate to h, then there exist points \(z_{0} \in \mathbb{D}\) and \(\zeta _{0} \in \partial \mathbb{D} \setminus \{ 1 \}\) satisfying (2.5) with \(\rho \in \mathbb{R}\).

Put \(\alpha = \alpha _{1} + {\mathrm{{i}}}\alpha _{2}\) with \(\alpha _{1} \geq 0\) and \(\alpha _{2}\in \mathbb{R}\). By (2.17) and (2.5), we obtain

Hence taking real parts in the above, and from \(\sigma \alpha _{1} \leq 0\) and \(m \geq 1\), we have

Now equation (2.6) gives

where

and

with \(\mu = \cos \beta -\gamma \).

Clearly, \(a_{2}>0\). Thus we have

Consequently, by (2.22), (2.23), and (2.24), we obtain

This contradicts (2.21). Therefore we obtain \(q \prec h\) in \(\mathbb{D}\), and it follows that the inequality \(\operatorname{Re}\{ {\mathrm{{e}}}^{{\mathrm{{i}}}\beta }p(z) \} > \gamma \) holds for all \(z\in \mathbb{D}\). □

Since the condition

implies

for \(w\in \mathbb{C}\), \(a \in \mathbb{R}\) and \(\beta \in (-\pi /2,\pi /2)\), by noting that \(\Psi (\alpha ,\beta ,\gamma ) = \Psi (\alpha ,-\beta ,\gamma )\), the following result can be obtained from Theorem 2.3.

Theorem 2.4

Let \(\alpha \in \mathbb{C}\) with \(\operatorname{Re}(\alpha )\geq 0\). Assume that \(\Psi (\alpha ,\beta ,\gamma ) < \cos \beta \), where Ψ is given by (2.20). If \(p \in {\mathcal{H}}_{1}\) satisfies

then

Taking \(\alpha =1\) and \(p(z)=zf'(z)/f(z)\), \(f \in {\mathcal{A}}\), in Theorems 2.3 and 2.4 we have the following corollary.

Corollary 2.3

Assume that \(\Psi (1,\beta ,\gamma ) < \cos \beta \), where Ψ is given by (2.20). If \(f \in {\mathcal{A}}\) satisfies

then f is a β-spirallike function of order γ in \(\mathbb{D}\). If \(f \in {\mathcal{A}}\) satisfies

then f is strongly starlike of order \(1-(2/\pi )\beta \) and type γ in \(\mathbb{D}\).

Example 2.3

Let \(a\in \mathbb{C}\), and define a function \(f_{a}:\mathbb{D}\rightarrow \mathbb{C}\) by \(f_{a}(z)=z/(1-az)\). Then, since \(|z|<1\), we have

or, equivalently,

By Corollary 2.3, \(f_{a}\) is a β-spirallike function of order γ provided

where Ψ is given by (2.20). In particular, if

then \(f_{a}\) is \((\pi /3)\)-spirallike function of order \(1/3\). Indeed, when \(\beta =\pi /3\) and \(\gamma =1/3\), we have \(\cos \beta - \Psi (1,\beta ,\gamma ) = 25/63\). Solving the inequality \(|a|(3+|a|)/(1-|a|)^{2} \leq 25/63\) gives us to get \(|a| \leq \tau \).

Example 2.4

Let \(a\in \mathbb{C}\) be given, and let \(g_{a}(z) = z/(1-az)^{2}\), \(z\in \mathbb{D}\). Then, from a similar computation with Example 2.3 and Corollary 2.3, we have that \(g_{a}\) is a β-spirallike function of order γ, if

In the present investigation, we have found several conditions for Carathéodory functions by using a technique of the first-order differential subordination. In particular, one can obtain conditions for Carathéodory functions of order γ (\(0 < \gamma \leq 1\)) and for tilted Carathéodory functions by angle β (\(-\pi /2 < \beta < \pi /2\)). We have applied these results to obtain new criteria for geometric properties such as spirallikeness and strongly starlikeness, and several examples were given here.

We conclude this paper by remarking that the results here reduce the earlier conditions [13] for Carathéodory functions. Also, as the examples in this paper show, the first-order differential subordination with the conformal mapping \(\varphi _{\beta ,\gamma }\) defined by (2.1) gives some nice criteria for spirallike functions and strongly starlike functions. This observation will indeed apply to any attempt to produce the conditions for other geometric properties such as convexity, q-starlikeness, etc. [1–3, 10, 22, 29, 30].

There is no additional data required for finding the results of this paper.

The first author was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF) funded by the Ministry of Education, Science and Technology (No. 2019R1I1A3A01050861).

There is no funding available for the publication of this paper.

Authors and Affiliations

1. Department of Applied Mathematics, Pukyong National University, Busan, 48513, Korea

   Nak Eun Cho

2. Department of Mathematics, Kyungsung University, Busan, 48434, Korea

   Oh Sang Kwon & Young Jae Sim

Contributions

All authors have equal contribution in this article. All authors read and approved the final manuscript.

Corresponding author

Correspondence to Young Jae Sim.

Competing interests

The authors declare that they have no competing interests.

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