Some Properties for Subordinations of Analytic Functions

Güney, Hatun Özlem; Breaz, Daniel; Owa, Shigeyoshi

doi:10.3390/axioms12020131

Open AccessArticle

Some Properties for Subordinations of Analytic Functions

by

Hatun Özlem Güney

¹

,

Daniel Breaz

²

and

Shigeyoshi Owa

^3,*

¹

Department of Mathematics, Faculty of Science, Dicle University, 21280 Diyarbakır, Türkiye

²

Department of Exact Sciences and Engineering, “1 Decembrie 1918” University Alba Iulia, 510009 Alba Iulia, Romania

³

“1 Decembrie 1918” University Alba Iulia, 510009 Alba-Iulia, Romania

^*

Author to whom correspondence should be addressed.

Axioms 2023, 12(2), 131; https://doi.org/10.3390/axioms12020131

Submission received: 13 December 2022 / Revised: 24 January 2023 / Accepted: 25 January 2023 / Published: 28 January 2023

(This article belongs to the Special Issue Dedicated to Professor Hari Mohan Srivastava on the Occasion of His 82nd Birthday)

Download Versions Notes

Abstract

:

Let the class of functions of

f (z)

of the form

f (z) = z + \sum_{k = 2}^{\infty} a_{k} z^{k}

, which are denoted by

A

and called analytic functions in the open-unit disk. There are many interesting properties of the functions

f (z)

in the class

A

concerning the subordinations. Applying the three lemmas for

f (z) \in A

provided by Miller and Mocanu and by Nunokawa, we consider many interesting properties of

f (z) \in A

with subordinations. Furthermore, we provide simple examples for our results. We think it is very important to consider examples of the results.

Keywords:

analytic function; starlike function of order α; convex function of order α; subordination; differential subordinaton

MSC:

30C45; 30C50

1. Introduction

Let

A

be the class of functions

f (z)

of the form:

f (z) = z + \sum_{k = 2}^{\infty} a_{k} z^{k}

(1)

which are analytic in the open-unit disk

U = {z \in C : | z | < 1} .

Given the two analytic functions

f (z)

and

g (z)

, the function

f (z)

is said to be subordinate to

g (z)

in

U

and written as

f (z) ≺ g (z)

if there exists a Schwarz function

w (z)

analytic such that

f (z) = g (w (z))

with

w (0) = 0

and

| w (z) | \leq 1,

z \in U .

In particular, if

g (z)

is univalent in

U,

then

f (z) ≺ g (z)

if and only if

f (0) = g (0)

and

f (U) \subseteq g (U)

(cf. [1,2]). We note that if

f (z) \in A

satisfies

\frac{z f^{'} (z)}{f (z)} ≺ \frac{1 + (1 - 2 α) z}{1 - z} (z \in U)

(2)

for some real

α (0 \leq α < 1),

then

f (z)

is said to be the starlike function of order

α

in

U

and, if

f (z) \in A

satisfies

1 + \frac{z f^{″} (z)}{f^{'} (z)} ≺ \frac{1 + (1 - 2 α) z}{1 - z} (z \in U)

(3)

for some real

α (0 \leq α < 1),

then

f (z)

is said to be the convex of order

α

in

U .

Furthermore, let

p (z)

be analytic in

U

and

p (0) = 1 .

Then, if

p (z)

satisfies

p (z) ≺ {(\frac{1 + z}{1 - z})}^{α} (z \in U)

(4)

for some real

α (α > 0),

then

p (z)

satisfies

| a r g p (z) | < \frac{π}{2} α (z \in U) .

(5)

If

f (z) \in A

satisfies

|a r g f^{'} (z)| < \frac{π}{2} α (z \in U)

(6)

for some real

α (0 < α \leq 1),

then we say that

f (z)

is the strongly univalent function of order

α

in

U .

If

f (z) \in A

satisfies

|a r g \frac{z f^{'} (z)}{f (z)}| < \frac{π}{2} α (z \in U)

(7)

for some real

α (0 < α \leq 1),

then we say that

f (z)

is the strongly starlike function of order

α

in

U .

Further, if

f (z) \in A

satisfies

|a r g (1 + \frac{z f^{″} (z)}{f^{'} (z)})| < \frac{π}{2} α (z \in U)

(8)

for some real

α (0 < α \leq 1),

then we say that

f (z)

is the strongly convex function of order

α

in

U

(cf. [2]).

2. Some Applications of Differential Subordinations

To consider some applications for subordinations, we introduce the following lemma from Miller and Mocanu [3].

Lemma 1.

Let

β_{0} = 1.21872 \dots

be the solution of

β π = \frac{3}{2} π - T a n^{- 1} β

and let

α = α (β) = β + 2 T a n^{- 1} (\frac{β}{π})

for

0 < β < β_{0} .

If

p (z)

is analytic in

U

with

p (0) = 1,

then

p (z) + z p^{'} (z) ≺ {(\frac{1 + z}{1 - z})}^{α}; (z \in U)

(9)

implies that

p (z) ≺ {(\frac{1 + z}{1 - z})}^{β}; (z \in U) .

(10)

Remark 1.

If

β = 1

in Lemma 1, then

α (1) = \frac{3}{2} .

Thus, Lemma 1 says that if the function

p (z)

satisfies the following subordination:

p (z) + z p^{'} (z) ≺ {(\frac{1 + z}{1 - z})}^{\frac{3}{2}}; (z \in U)

(11)

then

p (z) ≺ \frac{1 + z}{1 - z}; (z \in U) .

(12)

Now, we prove the following theorem.

Theorem 1.

Let

β_{0} = 1.21872 \dots

be the solution of

β π = \frac{3}{2} π - T a n^{- 1} β

and let

α = α (β) = β + 2 T a n^{- 1} (\frac{β}{π})

for

0 < β < β_{0} .

If

p (z)

is analytic in

U

with

p (0) = 1,

then

p (z) + z p^{'} (z) ≺ γ + (1 - γ) {(\frac{1 + z}{1 - z})}^{α}; (z \in U)

(13)

implies that

p (z) ≺ γ + (1 - γ) {(\frac{1 + z}{1 - z})}^{β}; (z \in U)

(14)

where

0 \leq γ < 1 .

Proof.

Let us define a function

F (z)

using

F (z) = \frac{p (z) - γ}{1 - γ}, (z \in U) .

(15)

Then,

F (z)

is analytic in

U

with

F (0) = 1

and

z F^{'} (z) = \frac{z p^{'} (z)}{1 - γ} .

(16)

Therefore, Lemma 1 implies that if

F (z) + z F^{'} (z) = \frac{p (z) + z p^{'} (z) - γ}{1 - γ} ≺ {(\frac{1 + z}{1 - z})}^{α}, (z \in U)

(17)

then

F (z) = \frac{p (z) - γ}{1 - γ} ≺ {(\frac{1 + z}{1 - z})}^{β}, (z \in U) .

(18)

The subordination (17) implies (13) and the subordination (18) is the same as (14). □

Letting

β = 1

in Theorem 1, we obtain the following corollary.

Corollary 1.

If

p (z)

is analytic in

U

with

p (0) = 1

satisfies

p (z) + z p^{'} (z) ≺ γ + (1 - γ) {(\frac{1 + z}{1 - z})}^{\frac{3}{2}}; (z \in U)

(19)

for some real γ

(0 \leq γ < 1)

then

p (z) ≺ \frac{1 + (1 - 2 γ) z}{1 - z}; (z \in U)

(20)

and

R e p (z) > γ (z \in U) .

In Corollary 1, considering

p (z) = \frac{f (z)}{z}

for the function

f (z)

in the class

A,

we have the following.

Corollary 2.

If the function

f (z)

in the class

A

satisfies

f^{'} (z) ≺ γ + (1 - γ) {(\frac{1 + z}{1 - z})}^{\frac{3}{2}}; (z \in U)

(21)

for some real γ

(0 \leq γ < 1)

then

\frac{f (z)}{z} ≺ \frac{1 + (1 - 2 γ) z}{1 - z}; (z \in U)

(22)

and

R e (\frac{f (z)}{z}) > γ (z \in U) .

In Corollary 1, ensuring

p (z) = f^{'} (z)

for the function

f (z)

in the class

A,

we have the following.

Corollary 3.

If the function

f (z)

in the class

A

satisfies

f^{'} (z) + z f^{''} (z) ≺ γ + (1 - γ) {(\frac{1 + z}{1 - z})}^{\frac{3}{2}}; (z \in U)

(23)

for some real γ

(0 \leq γ < 1),

then

f^{'} (z) ≺ \frac{1 + (1 - 2 γ) z}{1 - z}; (z \in U)

(24)

and

R e (f^{'} (z)) > γ (z \in U) .

Further, in Corollary 1, letting

p (z) = \frac{z f^{'} (z)}{f (z)}

for the function

f (z)

in the class

A,

we have the following corollary.

Corollary 4.

If the function

f (z)

in the class

A

satisfies

2 \frac{z f^{'} (z)}{f (z)} + \frac{z^{2} f^{″} (z)}{f (z)} - {(\frac{z f^{'} (z)}{f (z)})}^{2} ≺ γ + (1 - γ) {(\frac{1 + z}{1 - z})}^{\frac{3}{2}}; (z \in U)

(25)

for some real γ

(0 \leq γ < 1),

then

\frac{z f^{'} (z)}{f (z)} ≺ \frac{1 + (1 - 2 γ) z}{1 - z}; (z \in U)

(26)

and

f (z)

is the starlike function of order γ in

U .

To consider the next problem, let

P_{n}

be the class of functions

p (z)

that are analytic in

U

with

p (z) = 1 + \sum_{k = n}^{\infty} c_{n} z^{n} (n \in N = {1, 2, 3, \dots}) .

(27)

For

p (z) \in P_{n},

Nunokawa [4,5] derives the following lemma.

Lemma 2.

Let a function

p (z)

be in the class

P_{n} .

If there exists a point

z_{0} (| z_{0} | < 1)

such that

|a r g (p (z))| < \frac{π}{2} β (| z | < | z_{0} |)

(28)

and

|a r g (p (z_{0}))| = \frac{π}{2} β

(29)

for some real

β > 0,

then

\frac{z_{0} p^{'} (z_{0})}{p (z_{0})} = \frac{2 i m}{π} a r g (p (z_{0}))

(30)

for some

m \geq \frac{n}{2} (a + \frac{1}{a}) > n,

where

{(p (z_{0}))}^{\frac{1}{β}} = \pm i a (a > 0) .

(31)

Applying the Lemma 2, we derive the following theorem.

Theorem 2.

If the function

p (z)

in the class

P_{n}

satisfies

{\{\frac{p (z) - α}{1 - α} + \frac{z p^{'} (z)}{p (z) - α}\}}^{2} - 1 ≺ \frac{4 {(n + 1)}^{2} z}{{(1 - z)}^{2}}, (z \in U)

(32)

for some real

α (0 \leq α < 1),

then

R e (p (z)) > α, (z \in U) .

(33)

Proof.

We suppose that there exists a point

z_{0} (| z_{0} | < 1)

such that

Re \{\frac{p (z) - α}{1 - α}\} > 0 (| z | < | z_{0} | < 1)

(34)

and

Re \{\frac{p (z_{0}) - α}{1 - α}\} = 0 .

(35)

If

\frac{p (z_{0}) - α}{1 - α} \neq 0,

(36)

then Lemma 2 provides

\begin{matrix} \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α} & = \frac{2 i m}{π} a r g (\frac{p (z_{0}) - α}{1 - α}) \\ = \frac{2 i m}{π} a r g (p (z_{0}) - α) \end{matrix}

(37)

for some real

m \geq \frac{n}{2} (a + \frac{1}{a}) > n

with

{(\frac{p (z_{0}) - α}{1 - α})}^{\frac{1}{β}} = \pm i a (a > 0) .

(38)

It follows from the above that

\begin{matrix} {\{\frac{p (z_{0}) - α}{1 - α} + \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α}\}}^{2} - 1 & = {(\pm i a \pm i m)}^{2} - 1 \\ \leq - {(a + \frac{n (a^{2} + 1)}{2 a})}^{2} - 1 . \end{matrix}

(39)

We consider a function

h (a)

provided by

\begin{matrix} h (a) = a + \frac{n (a^{2} + 1)}{2 a} (a > 0) . \end{matrix}

(40)

Then,

h (a)

satisfies

\begin{matrix} h (a) \geq h (\sqrt{\frac{n}{n + 2}}) = \sqrt{n (n + 2)} . \end{matrix}

(41)

This implies that

\begin{matrix} {\{\frac{p (z_{0}) - α}{1 - α} + \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α}\}}^{2} - 1 & \leq - {(a + \frac{n (a^{2} + 1)}{2 a})}^{2} - 1 \\ = - {(n + 1)}^{2} . \end{matrix}

(42)

On the other hand, we consider a function

g (z)

provided by

\begin{matrix} g (z) = \frac{4 {(n + 1)}^{2} z}{{(1 - z)}^{2}} (z \in U) . \end{matrix}

(43)

The function

g (z)

maps

U

onto the domain with the slit

(- \infty, - {(n + 1)}^{2}) .

This contradicts our condition (31). Therefore, we have that

Re (\frac{p (z) - α}{1 - α}) > 0

(44)

for all

z \in U .

This shows us that

Re (p (z)) > α, (z \in U) .

(45)

□

Considering

p (z) = \frac{f (z)}{z}

for the function

f (z)

in the class

A,

we have the following corollary.

Corollary 5.

If the function

f (z)

in the class

A

satisfies

{\{\frac{f (z) - α}{z (1 - α)} + \frac{z f^{'} (z) - f (z)}{f (z) - z}\}}^{2} - 1 ≺ \frac{16 z}{{(1 - z)}^{2}}; (z \in U)

(46)

for some real α

(0 \leq α < 1),

then

R e \frac{f (z)}{z} > α; (z \in U) .

(47)

Causing

p (z) = f^{'} (z)

for the function

f (z)

in the class

A,

thus we obtain the following corollary.

Corollary 6.

If the function

f (z)

in the class

A

satisfies

{\{\frac{f^{'} (z) - α}{1 - α} + \frac{z f^{''} (z)}{f^{'} (z) - α}\}}^{2} ≺ \frac{16 z}{{(1 - z)}^{2}}; (z \in U)

(48)

for some real α

(0 \leq α < 1),

then

{R e f}^{'} (z) > α; (z \in U) .

(49)

Using

p (z) = \frac{z f^{'} (z)}{f (z)}

for the function

f (z)

in the class

A,

we have the following corollary.

Corollary 7.

If the function

f (z)

in the class

A

satisfies

{\{\frac{1}{f (z)} (\frac{z f^{'} (z) - α f (z)}{1 - α} + \frac{z (f (z) f^{'} (z) + z f (z) f^{″} (z) - z {(f^{'} (z))}^{2})}{z f^{'} (z) - α f (z)})\}}^{2} - 1 ≺ \frac{16 z}{{(1 - z)}^{2}}

(50)

for some real α

(0 \leq α < 1),

then

R e (\frac{z f^{'} (z)}{f (z)}) > α; (z \in U) .

(51)

Next, we derive the following theorem.

Theorem 3.

If the function

p (z)

in the class

P_{n}

satisfies

\frac{p (z) - α}{1 - α} + \frac{z p^{'} (z)}{p (z) - α} ≺ \frac{1 + z}{1 - z}, (z \in U)

(52)

for some real

α (0 \leq α < 1),

then

R e (p (z)) > α, (z \in U) .

(53)

Proof.

We consider that there exists a point

z_{0} (| z_{0} | < 1)

such that

Re \{\frac{p (z) - α}{1 - α}\} > 0 (| z | < | z_{0} | < 1)

(54)

and

Re \{\frac{p (z_{0}) - α}{1 - α}\} = 0 .

(55)

If

\frac{p (z_{0}) - α}{1 - α} \neq 0,

(56)

using Lemma 2 we have

\begin{matrix} \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α} = \frac{2 i m}{π} a r g (p (z_{0}) - α) \end{matrix}

(57)

for some real

m \geq \frac{n}{2} (a + \frac{1}{a}) > n

with

\frac{p (z_{0}) - α}{1 - α} = \pm i a (a > 0) .

(58)

This provides

\begin{matrix} \frac{p (z_{0}) - α}{1 - α} + \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α} & = \pm i a \pm i m \\ = \pm i (a + m) . \end{matrix}

(59)

Noting that

\begin{matrix} Re (\frac{1 + z}{1 - z}) > 0 (z \in U), \end{matrix}

(60)

we say that

\begin{matrix} \frac{p (z) - α}{1 - α} + \frac{z p^{'} (z)}{p (z) - α} i s n o t s u b o r d i n a t e t o \frac{1 + z}{1 - z} (z \in U) . \end{matrix}

(61)

Therefore, there is no

z_{0} (| z_{0} | < 1)

as in (34) and (35). This implies that

\begin{matrix} (\frac{p (z) - α}{1 - α}) > 0 (z \in U) \end{matrix}

(62)

that is

Re (p (z)) > α, (z \in U) .

(63)

□

Example 1.

Let us consider a function

p (z)

provided by

p (z) = \frac{1}{1 - z} \in P_{1}

(64)

and

α = 0 .

Then,

p (z)

satisfies

p (z) + \frac{z p^{'} (z)}{p (z)} = \frac{1 + z}{1 - z}, (z \in U) .

(65)

Thus,

p (z)

satisfies the subordination (52) for

α = 0 .

For such

p (z),

we have that

R e (p (z)) > \frac{1}{2} > 0, (z \in U) .

(66)

Corollary 8.

If the function

p (z)

in the class

P_{n}

satisfies

|a r g (\frac{p (z) - α}{1 - α} + \frac{z p^{'} (z)}{p (z) - α})| < \frac{π}{2}, (z \in U)

(67)

for some real

α (0 \leq α < 1),

then

R e (p (z)) > α, (z \in U) .

(68)

Corollary 9.

If the function

f (z)

in the class

A

satisfies

\frac{f^{'} (z) - α}{1 - α} + \frac{z f^{″} (z)}{f^{'} (z) - α} ≺ \frac{1 + z}{1 - z}; (z \in U)

(69)

for some real α

(0 \leq α < 1),

then

{R e f}^{'} (z) > α; (z \in U) .

(70)

Corollary 10.

If the function

f (z)

in the class

A

satisfies

\frac{f (z)}{z} + \frac{z f^{'} (z)}{f (z)} - 1 ≺ \frac{1 + z}{1 - z}; (z \in U)

(71)

for some real α

(0 \leq α < 1),

then

R e (\frac{f (z)}{z}) > 0; (z \in U) .

(72)

3. Applications of Miller–Mocanu Lemma

In this section, we would like to apply the Miller–Mocanu lemma [1,6] (also from Jack [7]).

Lemma 3.

Let

w (z)

be analytic in

U

with

w (0) = 0 .

Then, if

| w (z) |

attains its maximum value on the circle

| z | = r < 1

at a point

z_{0} \in U,

then we have

z_{0} w^{'} (z_{0}) = m w (z_{0})

(73)

and

R e (1 + \frac{z_{0} w^{″} (z_{0})}{w^{'} (z_{0})}) \geq m

(74)

where

m \geq 1 .

Theorem 4.

If the function

f (z)

in the class

A

satisfies

\frac{f (z)}{z} ≺ \frac{α (1 + z)}{α + (2 - α) z}; (z \in U)

(75)

for some real α

(α > 1),

then

|\frac{f (z)}{z} - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(76)

Proof.

Let us define a function

w (z)

using

\frac{f (z)}{z} = \frac{α (1 + w (z))}{α + (2 - α) w (z)}; (z \in U) .

(77)

Then,

w (z)

is analytic in

U

with

w (0) = 0

and

| w (z) | < 1 (z \in U) .

Letting

g (z) = \frac{f (z)}{z},

(78)

we see that

| w (z) | = |\frac{α (g (z) - 1)}{α - (2 - α) g (z)}| < 1; (z \in U) .

(79)

It follows from (79) that

{2 | g (z) |}^{2} - α (g (z) + \bar{g (z)}) < 0; (z \in U)

(80)

and that

|g (z) - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(81)

□

Next, we have the following theorem.

Theorem 5.

If the function

f (z)

in the class

A

satisfies

f^{'} (z) ≺ \frac{α (1 + z)}{α + (2 - α) z}; (z \in U)

(82)

for some real α

(α > 1),

then

|f^{'} (z) - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(83)

Proof.

Considering a function

w (z)

such that

f^{'} (z) = \frac{α (1 + w (z))}{α + (2 - α) w (z)}; (z \in U),

(84)

we prove the theorem. □

Remark 2.

The inequality (76) implies that

0 < R e (\frac{f (z)}{z}) < α; (z \in U)

(85)

and the inequality (83) implies that

0 < {R e f}^{'} (z) < α; (z \in U) .

(86)

The following theorem is our next result.

Theorem 6.

If the function

f (z)

in the class

A

satisfies

R e (\frac{z f^{'} (z)}{f (z)}) < 1 + \frac{α - 1}{2 δ}; (z \in U)

(87)

for some real α

(1 < α \leq 2)

or

R e (\frac{z f^{'} (z)}{f (z)}) < 1 + \frac{1}{2 δ (α - 1)}; (z \in U)

(88)

for some real α

(α > 2),

then

|{(\frac{f (z)}{z})}^{δ} - \frac{α}{2}| < \frac{α}{2}; (z \in U)

(89)

where

0 < δ \leq 1 .

Proof.

We define a function

w (z)

provided by

{(\frac{f (z)}{z})}^{δ} = \frac{α (1 + w (z))}{α + (2 - α) w (z)}; (z \in U)

(90)

for

0 < δ \leq 1 .

Then,

w (z)

is analytic in

U

with

w (0) = 0 .

This function

w (z)

satisfies

\frac{z f^{'} (z)}{f (z)} - 1 = \frac{z w^{'} (z)}{δ w (z)} (\frac{w (z)}{1 + w (z)} - \frac{(2 - α) w (z)}{α + (2 - α) w (z)}) .

(91)

Suppose that there exists a point

z_{0} \in U

such that

\max_{| z | \leq | z_{0} |} | w (z) | = | w (z_{0} | = 1 .

(92)

Then, Lemma 3 shows us that

z_{0} w^{'} (z_{0}) = m w (z_{0}) (m \geq 1)

(93)

and

w (z_{0}) = e^{i θ} (0 \leq θ < 2 π) .

It follows from the above that

\begin{matrix} Re (\frac{z_{0} f^{'} (z_{0})}{f (z_{0})}) & = Re (1 + \frac{m}{δ} (\frac{e^{i θ}}{1 + e^{i θ}} - \frac{(2 - α) e^{i θ}}{α + (2 - α) e^{i θ}})) \\ = 1 + \frac{m}{δ} (\frac{1}{2} + \frac{(α - 2) (2 - α + α c o s θ)}{α^{2} + {(2 - α)}^{2} + 2 α (2 - α) c o s θ}) . \end{matrix}

(94)

We consider a function

g (t)

provided by

g (t) = \frac{2 - α + α t}{α^{2} + {(2 - α)}^{2} + 2 α (2 - α) t} (t = c o s θ) .

(95)

It follows from (95) that

g^{'} (t) = \frac{4 α (α - 1)}{{(α^{2} + {(2 - α)}^{2} + 2 α (2 - α) t)}^{2}} > 0

(96)

for

α > 1 .

Since

g (t)

is increasing for

t = c o s θ,

we have

\begin{matrix} Re (\frac{z_{0} f^{'} (z_{0})}{f (z_{0})}) & \geq 1 + \frac{m}{δ} (\frac{1}{2} + \frac{α - 2}{2}) \geq 1 + \frac{α - 1}{2 δ} \end{matrix}

(97)

for

1 < α \leq 2

and

\begin{matrix} Re (\frac{z_{0} f^{'} (z_{0})}{f (z_{0})}) & \geq 1 + \frac{m}{δ} (\frac{1}{2} - \frac{α - 2}{2 (α - 1)}) \geq 1 + \frac{1}{2 δ (α - 1)} \end{matrix}

(98)

for

α > 2 .

Thus, inequalities (97) and (98) contradict the conditions (87) and (88). Therefore, we say that there is no

w (z)

such that

w (0) = 0

and

| w (z_{0}) | = 1

for

z_{0} \in U .

This implies that

| w (z) | < 1

for all

z \in U,

that is

\begin{matrix} | w (z) | = |\frac{α ({(\frac{f (z)}{z})}^{δ} - 1)}{α - (2 - α) {(\frac{f (z)}{z})}^{δ}}| < 1; (z \in U) . \end{matrix}

(99)

This completes the proof of the theorem. □

Using

δ = 1

in Theorem 6, we have the following corollary.

Corollary 11.

If the function

f (z)

in the class

A

satisfies

R e (\frac{z f^{'} (z)}{f (z)}) < \frac{α + 1}{2}; (z \in U)

(100)

for some real α

(1 < α \leq 2)

or

R e (\frac{z f^{'} (z)}{f (z)}) < \frac{2 α - 1}{2 (α - 1)}; (z \in U)

(101)

for some real α

(α > 2),

then

|\frac{f (z)}{z} - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(102)

Letting

δ = \frac{1}{2},

we have the following corollary.

Corollary 12.

If the function

f (z)

in the class

A

satisfies

R e (\frac{z f^{'} (z)}{f (z)}) < α; (z \in U)

(103)

for some real α

(1 < α \leq 2)

or

R e (\frac{z f^{'} (z)}{f (z)}) < \frac{α}{α - 1}; (z \in U)

(104)

for some real α

(α > 2),

then

|\sqrt{\frac{f (z)}{z}} - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(105)

Theorem 7.

If the function

f (z)

in the class

A

satisfies

R e (\frac{z f^{″} (z)}{f^{'} (z)}) < \frac{α - 1}{2 δ}; (z \in U)

(106)

for some real α

(1 < α \leq 2)

or

R e (\frac{z f^{″} (z)}{f^{'} (z)}) < \frac{1}{2 δ (α - 1)}; (z \in U)

(107)

for some real α

(α > 2),

then

|{(f^{'} (z))}^{δ} - \frac{α}{2}| < \frac{α}{2}; (z \in U)

(108)

where

0 < δ \leq 1 .

Proof.

Let us consider a function

w (z)

provided by

{(f^{'} (z))}^{δ} = \frac{α (1 + w (z))}{α + (2 - α) w (z)}; (z \in U)

(109)

for

0 < δ \leq 1 .

Then,

w (z)

is analytic in

U

with

w (0) = 0

and satisfies

\frac{z f^{″} (z)}{f^{'} (z)} = \frac{z w^{'} (z)}{δ w (z)} (\frac{w (z)}{1 + w (z)} - \frac{(2 - α) w (z)}{α + (2 - α) w (z)}) .

(110)

Therefore, applying Lemma 3 as the proof of Theorem 6, we prove the theorem. □

Using

δ = 1,

we have the following corollary.

Corollary 13.

If the function

f (z)

in the class

A

satisfies

R e (\frac{z f^{″} (z)}{f^{'} (z)}) < \frac{α - 1}{2}; (z \in U)

(111)

for some real α

(1 < α \leq 2)

or

R e (\frac{z f^{″} (z)}{f^{'} (z)}) < \frac{1}{2 (α - 1)}; (z \in U)

(112)

for some real α

(α > 2),

then

|f^{'} (z) - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(113)

Example 2.

We consider a function

f (z) \in A

provided by

f (z) = \frac{α}{2 - α} (z + \frac{2 (1 - α)}{2 - α} l o g (1 + \frac{2 - α}{α} z)) .

(114)

Then, we see

f^{'} (z) = \frac{α (1 + z)}{α + (2 - α) z}

(115)

and

f^{'} (z) - \frac{α}{2} = \frac{α ((2 - α) + α z)}{2 (α + (2 - α) z)} .

(116)

It follows from (116) that

|f^{'} (z) - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(117)

On the other hand,

f (z)

implies that

\frac{z f^{″} (z)}{f^{'} (z)} = \frac{z}{1 + z} - \frac{(2 - α) z}{α + (2 - α) z} .

(118)

Thus,

f (z)

satisfies the conditions (111) and (112) of Corollary 13.

Causing

δ = \frac{1}{2}

in Theorem 7, we have the following corollary.

Corollary 14.

If the function

f (z)

in the class

A

satisfies

R e (\frac{z f^{″} (z)}{f^{'} (z)}) < α - 1; (z \in U)

(119)

for some real α

(1 < α \leq 2)

or

R e (\frac{z f^{″} (z)}{f^{'} (z)}) < \frac{1}{α - 1}; (z \in U)

(120)

for some real α

(α > 2),

then

|\sqrt{f^{'} (z)} - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(121)

Further, we obtain the following theorem.

Theorem 8.

If the function

f (z)

in the class

A

satisfies

R e (1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)}) < \frac{α - 1}{2 δ}; (z \in U)

(122)

for some real α

(1 < α \leq 2)

or

R e (1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)}) < \frac{1}{2 δ (α - 1)}; (z \in U)

(123)

for some real α

(α > 2),

then

|{(\frac{z f^{'} (z)}{f (z)})}^{δ} - \frac{α}{2}| < \frac{α}{2}; (z \in U)

(124)

where

0 < δ \leq 1 .

Letting

δ = 1,

we obtain the following corollary.

Corollary 15.

If the function

f (z)

in the class

A

satisfies

R e (1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)}) < \frac{α - 1}{2}; (z \in U)

(125)

for some real α

(1 < α \leq 2)

or

R e (1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)}) < \frac{1}{2 (α - 1)}; (z \in U)

(126)

for some real α

(α > 2),

then

|\frac{z f^{'} (z)}{f (z)} - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(127)

Example 3.

We consider a function

f (z) \in A

provided by

f (z) = z {(α + (2 - α) z)}^{\frac{2 (α - 1)}{2 - α}}, (α \neq 2) .

(128)

It follows from (128) that

\frac{z f^{'} (z)}{f (z)} = \frac{α (1 + z)}{α + (2 - α) z}

(129)

and

1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)} = \frac{z}{1 + z} - \frac{(2 - α) z}{α + (2 - α) z} .

(130)

With (130), we know that

f (z)

satisfies the inequalities (125) and (126). Furthermore, by (129) we see that

f (z)

satisfies the inequality (127).

Letting

δ = \frac{1}{2}

in Theorem 8, we have the following corollary.

Corollary 16.

If the function

f (z)

in the class

A

satisfies

R e (1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)}) < α - 1; (z \in U)

(131)

for some real α

(1 < α \leq 2)

or

R e (1 + \frac{z f^{″} (z)}{f^{'} (z)} - \frac{z f^{'} (z)}{f (z)}) < \frac{1}{α - 1}; (z \in U)

(132)

for some real α

(α > 2),

then

|\sqrt{\frac{z f^{'} (z)}{f (z)}} - \frac{α}{2}| < \frac{α}{2}; (z \in U) .

(133)

In addition to our results given above, we can add the following:

In Theorem 3, we prove that if

p (z) \in P_{n}

satisfies the subordination (52), then

p (z)

satisfies the inequality (53). We know that

Re (\frac{1 + z}{1 - z}) > 0; (z \in U)

(134)

and

\frac{1 + e^{i θ}}{1 - e^{i θ}} = i c o t \frac{θ}{2}; (0 \leq θ < 2 π) .

(135)

Furthermore, Equation (59) implies that

Re \{\frac{p (z_{0}) - α}{1 - α} + \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α}\} = 0; (z \in U) .

(136)

Thus, we see that

|a r g {\{\frac{p (z_{0}) - α}{1 - α} + \frac{z_{0} p^{'} (z_{0})}{p (z_{0}) - α}\}}^{β}| > |a r g {(\frac{1 + z}{1 - z})}^{γ}|

(137)

for some real

β

and

γ

(0 < β \leq γ \leq 2) .

With the above comment, we derive the following theorem.

Theorem 9.

If

p (z) \in P_{n}

satisfies

{(\frac{p (z) - α}{1 - α} + \frac{z p^{'} (z)}{p (z) - α})}^{β} ≺ {(\frac{1 + z}{1 - z})}^{γ}, (z \in U)

(138)

for some real

α (0 \leq α < 1)

and for some real β and γ

(0 < β \leq γ \leq 2),

then

R e (p (z)) > α, (z \in U) .

(139)

Corollary 17.

If the function

p (z)

in the class

P_{n}

satisfies

|a r g {(\frac{p (z) - α}{1 - α} + \frac{z p^{'} (z)}{p (z) - α})}^{β}| < \frac{π}{2} β, (z \in U)

(140)

for some real

α (0 \leq α < 1)

and

β (0 < β \leq 2),

then

R e (p (z)) > α, (z \in U) .

(141)

Corollary 18.

If the function

f (z)

in the class

A

satisfies

|a r g {(\frac{f^{'} (z) - α}{1 - α} + \frac{z f^{″} (z)}{f^{'} (z) - α})}^{β}| < \frac{π}{2} β; (z \in U)

(142)

for some real

α (0 \leq α < 1)

and

β (0 < β \leq 2),

then

{R e f}^{'} (z) > α; (z \in U) .

(143)

Example 4.

We consider a function

f (z) \in A

provided by

f (z) = l o g (\frac{1}{1 - z}) .

(144)

Then, we have that

\begin{matrix} R e (\frac{f^{'} (z) - α}{1 - α} + \frac{z f^{″} (z)}{f^{'} (z) - α}) & = R e (\frac{1}{1 - α} (\frac{1}{1 - z} - α)) \\ > \frac{1 - 2 α}{1 - α} \geq 0; (z \in U) \end{matrix}

(145)

with

α (0 \leq α \leq \frac{1}{2}) .

This provides

\begin{matrix} |a r g {(\frac{f^{'} (z) - α}{1 - α} + \frac{z f^{″} (z)}{f^{'} (z) - α})}^{β}| < \frac{π}{2} β; (z \in U) \end{matrix}

(146)

with

α (0 \leq α \leq \frac{1}{2})

and

β (0 < β \leq 2) .

Furthermore, we have that

R e f^{'} (z) = R e (\frac{1}{1 - z}) > \frac{1}{2} \geq α; (z \in U) .

(147)

4. Conclusions

There are many interesting properties of functions

f (z)

that are analytic in the open-unit disk concerning subordinations. In this paper, we consider many interesting properties of

f (z)

that are analytic in the open-unit disk with subordinations by applying the three lemmas for

f (z)

provided by Miller and Mocanu and by Nunokawa. Furthermore, we provide simple examples for our results since we think it is very important to consider examples of the obtained results.

Author Contributions

Conceptualization, H.Ö.G., D.B. and S.O.; Investigation, H.Ö.G., D.B. and S.O.; Methodology, H.Ö.G., D.B. and S.O.; Writing—original draft, S.O.; Writing—review and editing, H.Ö.G., D.B. and S.O. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

References

Miller, S.S.; Mocanu, P.T. Differential Subordinations: Theory and Applications; Marcel Dekker Incorporated: New York, NY, USA; Basel, Switzerland, 2000. [Google Scholar]
Pommerenke, C. Univalent Functions; Vandenhoeck & Ruprecht: Göttingen, Germany, 1975. [Google Scholar]
Miller, S.S.; Mocanu, P.T. Marx-Strohhäcker differential subordination systems. Proc. Am. Math. Soc. 1987, 99, 527–534. [Google Scholar]
Nunokawa, M. On properties of non-Carathéodory functions. Proc. Jpn. Acad. Ser. Math. Sci. 1992, 68, 152–153. [Google Scholar] [CrossRef]
Nunokawa, M. On the order of strongly starlikeness of strongly convex functions. Proc. Jpn. Acad. Ser. A Math. Sci. 1993, 69, 234–237. [Google Scholar] [CrossRef]
Miller, S.S.; Mocanu, P.T. Second order differential inequalities in the complex plane. J. Math. Anal. Appl. 1978, 65, 289–305. [Google Scholar] [CrossRef] [Green Version]
Jack, I.S. Functions starlike and convex of order α. J. Lond. Math. Soc. 1971, 3, 469–474. [Google Scholar] [CrossRef]

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Güney, H.Ö.; Breaz, D.; Owa, S. Some Properties for Subordinations of Analytic Functions. Axioms 2023, 12, 131. https://doi.org/10.3390/axioms12020131

AMA Style

Güney HÖ, Breaz D, Owa S. Some Properties for Subordinations of Analytic Functions. Axioms. 2023; 12(2):131. https://doi.org/10.3390/axioms12020131

Chicago/Turabian Style

Güney, Hatun Özlem, Daniel Breaz, and Shigeyoshi Owa. 2023. "Some Properties for Subordinations of Analytic Functions" Axioms 12, no. 2: 131. https://doi.org/10.3390/axioms12020131

APA Style

Güney, H. Ö., Breaz, D., & Owa, S. (2023). Some Properties for Subordinations of Analytic Functions. Axioms, 12(2), 131. https://doi.org/10.3390/axioms12020131

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Some Properties for Subordinations of Analytic Functions

Abstract

1. Introduction

2. Some Applications of Differential Subordinations

3. Applications of Miller–Mocanu Lemma

4. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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