On a Harmonic Univalent Subclass of Functions Involving a Generalized Linear Operator

Yousef, Abdeljabbar Talal; Salleh, Zabidin

doi:10.3390/axioms9010032

Open AccessArticle

On a Harmonic Univalent Subclass of Functions Involving a Generalized Linear Operator

by

Abdeljabbar Talal Yousef

and

Zabidin Salleh

^*

Department of Mathematics, Faculty of Ocean Engineering Technology and Informatics, Universiti Malaysia Terengganu, Kuala Nerus 21030, Terengganu, Malaysia

^*

Author to whom correspondence should be addressed.

Axioms 2020, 9(1), 32; https://doi.org/10.3390/axioms9010032

Submission received: 5 March 2020 / Revised: 20 March 2020 / Accepted: 21 March 2020 / Published: 24 March 2020

(This article belongs to the Special Issue Differential and Difference Equations: A Themed Issue Dedicated to Prof. Hari M. Srivastava on the Occasion of his 80th Birthday)

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Abstract

:

In this paper, a subclass of complex-valued harmonic univalent functions defined by a generalized linear operator is introduced. Some interesting results such as coefficient bounds, compactness, and other properties of this class are obtained.

Keywords:

harmonic univalent functions; generalized linear operator; differential operator; Salagean operator; coefficient bounds

1. Introduction

Let

H

represent the continuous harmonic functions which are harmonic in the open unit disk

U = \{z : z \in ℂ, |z| < 1\}

and let

A

be a subclass of

H

which represents the functions which are analytic in

U

. A harmonic function in

U

could be expressed as

f = h + \bar{g}

, where

h

and

g

are in

A

,

h

is the analytic part of

f

,

g

is the co-analytic part of

f

and

|h' (z)| > |g' (z)|

is a necessary and sufficient condition for

f

to be locally univalent and sense-preserving in

U

(see Clunie and Sheil-Small [1]). Now we write,

h (z) = z + \sum_{n = 2}^{\infty} a_{n} z^{n}, g (z) = \sum_{n = 2}^{\infty} b_{n} z^{n} .

(1)

Let

S H

represents the functions of the form

f = h + \bar{g}

which are harmonic and univalent in

U

, which normalized by the condition

f (0) = f_{z} (0) - 1 = 0

. The subclass

S H^{0}

of

S H

consists of all functions in

S H

which have the additional property

f_{\bar{z}} (0) = 0

. The class

S H

was investigated by Clunie and Sheil-Smallas [1]. Since then, many researchers have studied the class

S H

and even investigated some subclasses of it. Also, we observe that the class

S H

reduces to the class

S

of normalized analytic univalent functions in

U

, if the co-analytic part of

f

is equal to zero. For

f \in S

, the Salagean differential operator

D^{n} (n \in ℕ_{0} = ℕ \cup \{0\})

was defined by Salagean [2]. For

f = h + \bar{g}

given by (1), Jahangiri et al. [3] defined the modified Salagean operator of

f

as

D^{m} f (z) = D^{m} h (z) + {(- 1)}^{m} \bar{D^{m} g (z)},

where

D^{m} h (z) = z + \sum_{n = 2}^{\infty} n^{m} a_{n} z^{n}, D^{m} g (z) = \sum_{n = 2}^{\infty} n^{m} b_{n} z^{n} .

Next, for functions

f \in A

, For

n \in ℕ_{0}, β \geq γ \geq 0

, Yalçın and Altınkaya [4] defined the differential operator of

I_{γ, β}^{m} f : S H^{0} \to S H^{0}

. Now we define our differential operator:

I_{δ, μ, λ, η, ς, τ}^{0} f (z) = h (z) + \bar{g (z)} I_{δ, μ, λ, ς, τ}^{1} f (z) = z + \sum_{n = 2}^{\infty} (\frac{μ + λ - (δ - ς) (λ - τ) D^{0} f (z) + (δ - ς) (λ - τ) D^{1} f (z)}{μ + λ}) = \frac{μ + λ - (δ - ς) (λ - τ) (h (z) + \bar{g (z)}) + (δ - ς) (λ - τ) (z h (z) + z \bar{g^{'} (z)})}{μ + λ}

(2)

I_{δ, μ, λ, ς, τ}^{m} f (z) = I_{δ, μ, λ, ς, τ}^{1} (I_{δ, μ, λ, ς, τ}^{m - 1} f (z)) .

(3)

If

f

is given by (1), then from (2) and (3), we get (see [5])

I_{δ, μ, λ, ς, τ}^{m} f (z) = z + \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} a_{n} z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \bar{b_{n} z^{n}} .

(4)

The operator

I_{δ, μ, λ, ς, τ}^{m} f (z)

generalizes the following differential operators:

If

f \in A,

then when we take

μ = 1, λ = 0, δ = 0, τ = 1, ς = 1

we obtain

I_{0, τ, δ, ς}^{m} f (z)

was introduced and studied by Ramadan and Darus [6]. By taking different choices of

μ, λ, δ, τ a n d ς

we get

I_{1 - λ, τ, 0, ς}^{m} f (z)

was introduced and studied by Darus and Ibrahim [7],

I_{μ, λ, 0, 1, 0}^{m} f (z)

was introduced and studied by Swamy [8],

I_{1 - λ, 0, 1,0}^{m} f (z)

was introduced and studied by Al-Oboudi [9] and

I_{0, 0,, 1, 0}^{m} f (z)

was introduced and studied by Salagean [2].

If

f \in H,

then

I_{μ, λ, 0, 1, 0}^{m} f (z)

becomes the modified Salagean operator introduced by Yasar and Yalçin [10].

A function

f : U \to C

is subordinate to the function

g : U \to C

denoted by

f (z) ≺ g (z)

, if there exists an analytic function

w : U \to U

with

w (0) = 0

such that

f (z) = g (w (z)), (z \in U) .

Moreover, if the function

g

is univalent in

U

, then we have (see [11,12]):

f (z) ≺ g (z) if and only if f (0) = g (0), f (U) \subset g (U) .

Denote by

S H^{0} (δ, μ, λ, ς, τ, m, A, B)

the subclass of

S H^{0}

consisting of functions of the form (1) that satisfy the condition

\frac{I_{δ, μ, λ, ς, τ}^{m + 1} f (z)}{I_{δ, μ, λ, ς, τ}^{m} f (z)} ≺ \frac{1 + A z}{1 + B z}, - 1 \leq A < B \leq 1

(5)

where

I_{δ, μ, λ, η, ς, τ}^{m} f (z)

is defined by (4). For relevant and recent references related to this work, we refer the reader to [13,14,15,16,17,18,19,20].

In this paper we use the same techniques that have been used earlier by Dziok [21] and Dziok et al. [22], to investigate coefficient bound, distortion bounds, and some other properties for the class

S H^{0} (δ, μ, λ, ς, τ, m, A, B)

.

2. Coefficient Bounds

In this section we find the coefficient bound for the class

S H^{0} (δ, μ, λ, ς, τ, m, A, B) .

Theorem 1.

Let the function

f (z) = h + \bar{g}

be defined by (1). Then

f \in S H^{0} (δ, μ, λ, ς, τ, m, A, B)

if

\sum_{n = 2}^{\infty} (C_{n} |a_{n}| + D_{n} |b_{n}|) \leq B - A

(6)

where

C_{n} = {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \{\frac{(δ - ς) (λ - τ) (n - 1) [B + 1] - (μ + λ) (B - A)}{μ + λ}\}

(7)

and

D_{n} = {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \{\frac{[A + B (2 + (δ - ς) (λ - τ) (n - 1))] (μ + λ)}{μ + λ}\} .

(8)

Proof.

Let

a_{n} \neq 0

or

b_{n} \neq 0

for

n \geq 2

. Since

C_{n}, D_{n} \geq n (B - A)

by (6), we obtain

|h^{'} (z)| - |g^{'} (z)| \geq 1 - \sum_{n = 2}^{\infty} n |a_{n}| {|z|}^{n - 1} - \sum_{n = 2}^{\infty} n |b_{n}| {|z|}^{n - 1} \geq 1 - |z| \sum_{n = 2}^{\infty} (n |a_{n}| + n |b_{n}|) \geq 1 - \frac{|z|}{B - A} \sum_{n = 2}^{\infty} (C_{n} |a_{n}| + D_{n} |b_{n}|) \geq 1 - |z| > 0

.

Therefore,

f

is univalent in

U

. To ensure the univalence condition, consider

z_{1}, z_{2} \in U

so that

z_{1} \neq z_{2}

. Then

|\frac{z_{1}^{n} - z_{2}^{n}}{z_{1} - z_{2}}| = |\sum_{m = 1}^{n} z_{1}^{m - 1} - z_{2}^{n - m}| \leq \sum_{m = 1}^{n} |z_{1}^{m - 1}| |z_{2}^{n - m}| < n, n \geq 2

.

So, we have

|\frac{f (z_{1}) - f (z_{2})}{h (z_{1}) - h (z_{2})}| \geq 1 - |\frac{g (z_{1}) - g (z_{2})}{h (z_{1}) - h (z_{2})}| = 1 - |\frac{\sum_{n = 2}^{\infty} b_{k} (z_{1}^{n} - z_{2}^{n})}{z_{1} - z_{2} + \sum_{n = 2}^{\infty} a_{n} (z_{1}^{n} - z_{2}^{n})}| > 1 - \frac{\sum_{n = 2}^{\infty} n |b_{n}|}{1 - \sum_{n = 2}^{\infty} n |a_{n}|} \geq 1 - \frac{\sum_{n = 2}^{\infty} \frac{D_{n}}{B - A} |b_{n}|}{\sum_{n = 2}^{\infty} \frac{C_{n}}{B - A} |a_{n}|} \geq 0,

which proves univalences.

On the other hand,

f \in S H^{0} (δ, μ, λ, ς, τ, m, A, B)

if and only if there exists a function

w

; with

w (0) = 0

, and

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

such that

\frac{I_{δ, μ, λ, ς, τ}^{m + 1} f (z)}{I_{δ, μ, λ, ς, τ}^{m} f (z)} ≺ \frac{1 + A z}{1 + B z}

or

\frac{I_{δ, μ, λ, ς, τ}^{m + 1} f (z) - I_{δ, μ, λ, ς, τ}^{m} f (z)}{B I_{δ, μ, λ, ς, τ}^{m + 1} f (z) - A I_{δ, μ, λ, ς, τ}^{m} f (z)} < 1, (z \in U) .

(9)

The above inequality (9) holds, since for

|z| = r (0 < r < 1)

we obtain

|I_{δ, μ, λ, ς, τ}^{m + 1} f (z) - I_{δ, μ, λ, ς, τ}^{m} f (z)| - |B I_{δ, μ, λ, ς, τ}^{m + 1} f (z) - A I_{δ, μ, λ, ς, τ}^{m} f (z)| = |\sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \frac{(δ - ς) (λ - τ) (n - 1)}{μ + λ} a_{n} z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \frac{2 (μ + λ) + (δ - ς) (λ - τ) (n - 1)}{μ + λ} \bar{b_{n} z^{n}}| - |(B - A) z + \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} (B \frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ} - A) a_{n} z^{n} - {(- 1)}^{m} \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} (B, \frac{2 (μ + λ) + δ (- ς) (λ - τ) (1 - n)}{μ + λ} + A) \bar{b_{n} z^{n}}| \leq \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \frac{(δ - ς) (λ - τ) (n - 1)}{μ + λ} |a_{n}| r^{n} + \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \frac{2 (μ + λ) + (δ - ς) (λ - τ) (1 - n)}{μ + λ} |b_{n}| r^{n} - (B - A) r + \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} (B \frac{μ + λ + (δ - ς) (λ - τ) (n - 1) + A}{μ + λ} - A) |a_{n}| r^{n} + \sum_{n = 2}^{\infty} {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} (B \frac{2 (μ + λ) + (δ - ς) (λ - τ) (n - 1)}{μ + λ} + A) |b_{n}| r^{n} \leq r \{\sum_{n = 2}^{\infty} (C_{n} |a_{n}| + D_{n} |b_{n}|) r^{n - 1} - (B - A)\} < 0 .

Therefore,

f \in S H^{0} (δ, μ, λ, ς, τ, m, A, B)

, and so the proof is completed.

Next we show that the condition (6) is also necessary for the functions

f \in H

to be in the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B) = T^{m} \cap S H^{0} (δ, μ, λ, ς, τ, m, A, B)

where

T^{m}

is the class of functions

f = h + \bar{g} \in S H^{0}

so that

f = h + \bar{g} = z - \sum_{n = 2}^{\infty} a_{n} z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} |b_{n}| \bar{z^{n}} (z \in U) .

(10)

□

Theorem 2.

Let

f = h + \bar{g}

be defined by (10). Then

f \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

if and only if the condition (6) holds.

Proof.

For this proof, we let the fractions

\frac{(δ - ς) (λ - τ) (n - 1)}{μ + λ} = L

and

\frac{2 (μ + λ) + (δ - ς) (λ - τ) (n - 1)}{μ + λ} = K

. The first part “if statement” follows from Theorem 1. Conversely, we suppose that

f \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

, then by (9) we have

|\frac{\sum_{n = 2}^{\infty} [{(L)}^{m} \frac{(δ - ς) (λ - τ) (n - 1)}{μ + λ} |a_{n}| z^{n} + {(K)}^{m} \frac{2 (μ + λ) + (δ - ς) (λ - τ) (n - 1)}{μ + λ} \bar{|b_{n}| z^{n}}]}{(B - A) z - \sum_{n = 2}^{\infty} [{(L)}^{m} (B L - A) |a_{n}| z^{n} + {(K)}^{m} (B K + A) |b_{n}| z^{n}]}| < 1 .

For

|z| = r < 1

, we obtain

\frac{\sum_{n = 2}^{\infty} [{(L)}^{m} \frac{(δ - ς) (λ - τ) (n - 1)}{μ + λ} |a_{n}| + {(K)}^{m} \frac{2 (μ + λ) + (δ - ς) (λ - τ) (n - 1)}{μ + λ} \bar{|b_{n}|}] r^{n - 1}}{(B - A) - \sum_{n = 2}^{\infty} [{(L)}^{m} (B L - A) |a_{n}| + {(K)}^{m} (B K + A) |b_{n}|] r^{n - 1}} < 1 .

Thus, for

C_{n}

and

D_{n}

as defined by (7) and (8), we have

\sum_{n = 2}^{\infty} [C_{n} |a_{n}| + D_{n} |b_{n}|] r^{n - 1} < B - A (0 \leq r < 1) . (11)

(11)

Let

\{ρ_{n}\}

be the sequence of partial sums of the series

\sum_{k = 2}^{n} [C_{k} |a_{k}| + D_{k} |b_{k}|] .

Then

\{ρ_{n}\}

is a non-decreasing sequence and by (11) it is bounded above by

B - A

. Thus, it is convergent and

\sum_{n = 2}^{\infty} [C_{n} |a_{n}| + D_{n} |b_{n}|] = \lim_{n \to + \infty} ρ_{n} \leq B - A .

This gives us the condition (6).□

3. Compactness and Convex

In this section we obtain the compactness and the convex relation for the class

S H^{0} (δ, μ, λ, ς, τ, m, A, B) .

Theorem 3.

The class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

is convex and compact subset of

S H .

Proof.

Let

f_{t} \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B),

where

f_{t} (z) = z - \sum_{n = 2}^{\infty} |a_{t, n}| z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} |b_{t, n}| \bar{z^{n}} (z \in U, t \in ℕ) .

(12)

Then for

0 \leq ψ \leq 1

, let

f_{1}, f_{2} \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

be defined by (12). Then

ξ (z) = ψ f_{1} (z) + (1 - ψ) f_{2} (z) = z - \sum_{n = 2}^{\infty} (ψ |a_{1, n}| + (1 - ψ) |a_{2, n}|) z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} (ψ |b_{1, n}| + (1 - ψ) |b_{2, n}|) \bar{z^{n}}

and

\sum_{n = 2}^{\infty} \{C_{n} (ψ |a_{1, n}| + (1 - ψ) |a_{2, n}|) + D_{n} (ψ |b_{1, n}| + (1 - ψ) |b_{2, n}|)\} = ψ \sum_{n = 2}^{\infty} \{C_{n} |a_{1, n}| + D_{n} |b_{1, n}|\} + (1 - ψ) \sum_{n = 2}^{\infty} \{C_{n} |a_{2, n}| + D_{n} |b_{2, n}|\} \leq ψ (B - A) + (1 - ψ) (B - A) = B - A .

Thus, the function

ξ = ψ f_{1} (z) + (1 - ψ) f_{2} (z)

is in the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

. This implies that

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

is convex.

For

f_{t} \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B), t \in ℕ

and

|z| \leq r (0 < r < 1),

then we have

|f_{t} (z)| \leq r + \sum_{n = 2}^{\infty} \{|a_{t, n}| + |b_{t, n}|\} r^{n} \leq r + \sum_{n = 2}^{\infty} \{C_{n} |a_{t, n}| + D_{n} |b_{t, n}|\} r^{n} \leq r + (B - A) r^{2} .

Therefore,

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

is uniformly bounded. Let

f_{t} (z) = z - \sum_{n = 2}^{\infty} |a_{t, n}| z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} |b_{t, n}| \bar{z^{n}} (z \in U, t \in ℕ) .

also, let

f = h + \bar{g}

where

h

and

g

are given by (1). Then by Theorem 2 we get

\sum_{n = 2}^{\infty} \{C_{n} |a_{n}| + D_{n} |b_{t, n}|\} \leq B - A .

(13)

If we assume

f_{t} \to f,

then we get that

|a_{t, n}| \to |a_{n}|

and

|b_{t, n}| \to |b_{n}|

as

n \to + \infty (t \in ℕ) .

Let

\{ρ_{n}\}

be the sequence of partial sums of the series

\sum_{n = 2}^{\infty} \{C_{n} |a_{t, n}| + D_{n} |b_{t, n}|\}

. Then

\{ρ_{n}\}

is a non-decreasing sequence and by (13) it is bounded above by

B - A

. Thus, it is convergent and

\sum_{n = 2}^{\infty} \{C_{n} |a_{t, n}| + D_{n} |b_{t, n}|\} = \lim_{n \to \infty} ρ_{n} \leq B - A .

Therefore,

f \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

and therefore the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

is closed. As a result, the class is closed, and the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

is also compact subset of

S H,

which completes the proof.□

Lemma 1

[23]. Let

f = h + \bar{g}

be so that

h

and

g

are given by (1). Furthermore, let

\sum_{n = 2}^{\infty} \{\frac{n - α}{1 - α} |a_{n}| + \frac{n + α}{1 - α} |b_{n}|\} \leq 1 (z \in U)

where

0 \leq α < 1

. Then

f

is harmonic, orientation preserving, univalent in

U

and

f

is starlike of order

α

.

Theorem 4.

Let

0 \leq α < 1, C_{n}

and

D_{n}

be defined by (7) and (8). Then

r_{α}^{*} (S H_{T}^{0} (δ, μ, λ, ς, τ, n, A, B)) = \inf_{n \geq 2} {[\frac{1 - α}{B - A} \min \{\frac{C_{n}}{n + α}, \frac{D_{n}}{n + α}\}]}^{\frac{1}{n - 1}},

(14)

where

r_{α}^{*}

is the radius of starlikeness of order

α .

Proof.

Let

f \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

be of the form (10). Then, for

|z| = r < 1

, we get

|\frac{I_{0, η} f (z) - (1 + α) f (z)}{I_{0, η} f (z) + (1 + α) f (z)}| = |\frac{- α z - \sum_{n = 2}^{\infty} (n - 1 - α) |a_{n}| z^{n} - {(- 1)}^{m} \sum_{n = 2}^{\infty} (n + 1 + α) |b_{n}| \bar{z^{n}}}{(2 - α) z - \sum_{n = 2}^{\infty} (n - 1 - α) |a_{n}| z^{n} - {(- 1)}^{m} \sum_{n = 2}^{\infty} (n - 1 + α) |b_{n}| \bar{z^{n}}}| \leq \frac{α - \sum_{n = 2}^{\infty} \{(n - 1 - α) |a_{n}| - {(- 1)}^{m} \sum_{n = 2}^{\infty} (n + 1 + α) |b_{n}|\} r^{n - 1}}{2 - α - \sum_{n = 2}^{\infty} \{(n - 1 - α) |a_{n}| - {(- 1)}^{m} \sum_{n = 2}^{\infty} (n - 1 + α) |b_{n}|\}} .

By using Lemma 1, we observe that f is starlike of order

α

in

U_{r}

if and only if

|\frac{I_{0, η} f (z) - (1 + α) f (z)}{I_{0, η} f (z) + (1 + α) f (z)}| < 1, z \in U_{r}

or

\sum_{n = 2}^{\infty} \{\frac{n - α}{1 - α} |a_{n}| + \frac{n + α}{1 - α} |b_{n}|\} r^{n - 1} \leq 1 .

(15)

Furthermore, by using Theorem 2, we get

\sum_{n = 2}^{\infty} \{\frac{C_{n}}{1 - α} |a_{n}| + \frac{D_{n}}{1 - α} |b_{n}|\} r^{n - 1} \leq 1 .

Condition (15) is true if

\frac{n - α}{1 - α} r^{n - 1} \leq \frac{C_{n}}{B - A} r^{n - 1} .

This proves

\frac{n + α}{1 - α} r^{n - 1} \leq \frac{D_{n}}{B - A} r^{n - 1} (n = 2, 3 \dots) .

So, the function

f

is starlike of order

α

in the disk

U_{r_{α}}^{*}

where

r_{α}^{*} = \inf_{n \geq 2} {[\frac{1 - α}{B - A} \min \{\frac{C_{n}}{n + α}, \frac{D_{n}}{n + α}\}]}^{\frac{1}{n - 1}},

and the function

f_{n} (z) = h_{n} (z) + \bar{g_{n} (z)} = z - \frac{B - A}{C_{n}} z^{n} + {(- 1)}^{m} \frac{B - A}{D_{n}} \bar{z^{n}} .

So, the radius

r_{α}^{*}

cannot be larger. Then we get (14).□

4. Extreme Points

In this section we find the extreme points for the class

S H^{0} (δ, μ, λ, ς, τ, m, A, B) .

Theorem 5.

The extreme points of

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

are the functions

f

of the form (1) where

h = h_{k}

and

g = g_{k}

are of the form

h_{1} (z) = z, h_{n} (z) = z - \frac{B - A}{C_{n}} z^{n}, g_{n} (z) = {(- 1)}^{m} \frac{B - A}{D_{n}} \bar{z^{n}}, (z \in U, n \geq 2) .

(16)

Proof.

Suppose that

g_{n} = ψ f_{1} + (1 - ψ) f_{2}

where

0 < ψ < 1

and

f_{1}, f_{2} \in S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

are written in the form

f_{t} (z) = z - \sum_{n = 2}^{\infty} |a_{t, n}| z^{n} + {(- 1)}^{m} \sum_{n = 2}^{\infty} |b_{t, n}| \bar{z^{n}} (z \in U, t \in \{1,2\}) .

Then, by (16), we get

|b_{1, n}| = |b_{2, n}| = \frac{B - A}{D_{n}},

and

a_{1, t} = a_{2, t} = 0

for

t \in \{2, 3 \dots\}

and

b_{1, t} = b_{2, t} = 0

for

t \in \{2, 3 \dots\} ∖ \{n\}

. It follows that

g_{n} (z) = f_{1} (z) = f_{2} (z)

and

g_{n}

are in the class of extreme points of the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

. We also can ensure that the functions

h_{n} (z)

are the extreme points of the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B) .

Now, assume that a function

f

of the form (1) is in the class of the extreme points of the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

and

f

is not of the form (16). Then there exists

k \in \{2, 3 \dots\}

such that

0 < |a_{k}| < \frac{B - A}{{(\frac{μ + λ + (δ - ς) (λ - τ) (k - 1)}{μ + λ})}^{m} \{\frac{(δ - ς) (λ - τ) [(k - 1) (B + 1)] + (μ + λ) (B - A)}{μ + λ}\}}

or

0 < |b_{k}| < \frac{B - A}{{(\frac{μ + λ - (δ - ς) (λ - τ) (n + 1)}{μ + λ})}^{m} \{\frac{[A + B (2 + (δ - ς) (λ - τ) (n - 1))] (μ + λ)}{μ + λ}\}} .

If

0 < |a_{k}| < \frac{B - A}{{(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \{\frac{(δ - ς) (λ - τ) (n - 1) [B + 1] - (μ + λ) (B - A)}{μ + λ}\}}

then putting

ψ = \frac{|a_{k}| [{(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \{\frac{(δ - ς) (λ - τ) (n - 1) [B + 1] - (μ + λ) (B - A)}{μ + λ}\}]}{B - A}

and

χ = \frac{f - ψ h_{k}}{1 - ψ},

we have

0 < ψ < 1

,

h_{k} \neq χ

. Therefore,

f

is not in the class of the extreme points of the class

S H_{T}^{0} (δ, μ, λ, η, ς, τ, m, A, B)

. Similarly, if

0 < |b_{k}| < \frac{B - A}{{(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \{\frac{[A + B (2 + (δ - ς) (λ - τ) (n - 1))] (μ + λ)}{μ + λ}\}}

then putting

ψ = \frac{|b_{k}| {(\frac{μ + λ + (δ - ς) (λ - τ) (n - 1)}{μ + λ})}^{m} \{\frac{[A + B (2 + (δ - ς) (λ - τ) (n - 1))] (μ + λ)}{μ + λ}\}}{B - A}

and

χ = \frac{f - ψ g_{k}}{1 - ψ},

we have

0 < ψ < 1

,

g_{k} \neq χ

. It follows that

f

is not in the family of extreme points of the class

S H_{T}^{0} (δ, μ, λ, ς, τ, m, A, B)

and so the proof is completed.□

Author Contributions

Conceptualization, A.T.Y. and Z.S.; methodology, A.T.Y.; software, A.T.Y.; validation, A.T.Y. and Z.S.; formal analysis, A.T.Y.; investigation, A.T.Y.; resources, A.T.Y.; data curation, A.T.Y.; writing—original draft preparation, A.T.Y.; writing—review and editing, Z.S.; visualization, Z.S.; supervision, Z.S.; project administration, Z.S.; funding acquisition, Z.S. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

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Yousef, A.T.; Salleh, Z. On a Harmonic Univalent Subclass of Functions Involving a Generalized Linear Operator. Axioms 2020, 9, 32. https://doi.org/10.3390/axioms9010032

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Yousef AT, Salleh Z. On a Harmonic Univalent Subclass of Functions Involving a Generalized Linear Operator. Axioms. 2020; 9(1):32. https://doi.org/10.3390/axioms9010032

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Yousef, Abdeljabbar Talal, and Zabidin Salleh. 2020. "On a Harmonic Univalent Subclass of Functions Involving a Generalized Linear Operator" Axioms 9, no. 1: 32. https://doi.org/10.3390/axioms9010032

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On a Harmonic Univalent Subclass of Functions Involving a Generalized Linear Operator

Abstract

1. Introduction

2. Coefficient Bounds

3. Compactness and Convex

4. Extreme Points

Author Contributions

Funding

Conflicts of Interest

References

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