On Meromorphic Parabolic Starlike Functions with Fixed Point Involving the q-Hypergeometric Function and Fixed Second Coefficients

Almutairi, Norah Saud; Shahen, Awatef; Darwish, Hanan

doi:10.3390/math11132991

Open AccessArticle

On Meromorphic Parabolic Starlike Functions with Fixed Point Involving the q-Hypergeometric Function and Fixed Second Coefficients

by

Norah Saud Almutairi

^*,

Awatef Shahen

and

Hanan Darwish

Department of Mathematics, Faculty of Science, Mansoura University, Mansoura 35516, Egypt

^*

Author to whom correspondence should be addressed.

Mathematics 2023, 11(13), 2991; https://doi.org/10.3390/math11132991

Submission received: 15 May 2023 / Revised: 20 June 2023 / Accepted: 27 June 2023 / Published: 4 July 2023

(This article belongs to the Special Issue New Trends in Complex Analysis Research, 2nd Edition)

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Abstract

:

This article defines a new class of meromorphic parabolic starlike functions in the punctured unit disc

D^{*} = {z \in C : 0 < | z | < 1}

that includes fixed second coefficients of class

A_{s, c}^{d} (ψ, τ, ν, η)

and the q- hypergeometric functions. For the function belonging to the class

A_{s, c}^{d} (ψ, τ, ν, η),

some properties are obtained, including the coefficient inequalities, closure theorems, and the radius of convexity.

Keywords:

meromorphic parabolic functions; univalent; starlike function; q-hypergeometric function

MSC:

30C45

1. Introduction

Let

η

be a fixed point in the unit disc

D : = {z \in C : | z | < 1}

. Using

H (D)

, denote the class of functions that are regular and

A (η) = {f \in H (D) : f (η) = f^{^{'}} (η) - 1 = 0}

Using

S_{η} = {f \in A (η), d e n o t e t h e f o l l o w i n g : f

is univalent in D}, the subclass of

A (η)

consisting of the functions of the form

ζ (z) = z - η + \sum_{l = 1}^{\infty} a_{l} {(z - η)}^{l} .

Let

ϰ

denote the class of meromorphic functions

ζ (z)

of the form

ζ (z) = \frac{1}{z} + \sum_{l = 1}^{\infty} a_{l} z^{l}

(1)

defined on the punctured unit disc

D^{*} = {z \in C : 0 < | z | < 1}

.

Using

ϰ_{η}

, denote the subclass of

ϰ

consisting of the form’s functions

ζ (z) = \frac{1}{z - η} + \sum_{l = 1}^{\infty} a_{l} {(z - η)}^{l}, a_{l} \geq 0; z \neq η, z \in D .

(2)

If a function

ζ (z)

of the form (2) belongs to the class of meromorphic starlike of order

σ

(0 \geq σ < 1)

, it is indicated by

ϰ_{η}^{*} (σ)

, if

- ℜ (\frac{(z - η) ζ^{^{'}} (z)}{ζ (z)}) > σ, z \neq η, z \in D,

(3)

and belongs to a class of meromorphic convex of order

σ (0 \leq σ < 1)

, which is indicated by

ϰ_{η}^{k} (σ)

, if

- ℜ (1 + \frac{(z - η) ζ^{^{''}} (z)}{ζ^{^{'}} (z)}) > σ, z \neq η, z \in D .

(4)

For functions

ζ (z)

, given by (2) and

g (z) = \frac{1}{z - η} + \sum_{l = 1}^{\infty} b_{l} {(z - η)}^{l}

,

(b_{l} \geq 0)

, we define the Hadamard product or convolution of

ζ (z)

and

g (z)

by

(ζ * g) (z) = \frac{1}{z - η} + \sum_{l = 1}^{\infty} a_{l} b_{l} {(z - η)}^{l} = (g * ζ) (z) .

(5)

Define the following operator [1].

q_{μ, ξ} (z) = \frac{1}{z - η} + \sum_{l = 1}^{\infty} {(\frac{μ}{l + 1 + μ})}^{ξ} {(z - η)}^{l}, (μ > 0, ξ \geq 0) .

(6)

Cho [2], Ghanim, and Darus [3] studied the above function when

η = 0

.

Corresponding to the function

q_{μ, ξ} (z)

and using the Hadamard product for

ζ (z) \in ϰ_{η},

we define a new linear operator

J (μ, ξ, η)

on

ϰ_{η} (σ)

by

J_{μ, ξ} ζ (z) = (ζ (z) * q_{μ, ξ} (z)) = \frac{1}{z - η} + \sum_{l = 1}^{\infty} {(\frac{μ}{l + 1 + μ})}^{ξ} | a_{l} | {(z - η)}^{l} .

(7)

When

η = 0

, it reduces to Ghanim and Darus [4].

A generalized q-Taylars formula for fractional q-calculus was introduced more recently by Purohit and Raina [5], who also derived a few q-generating functions for q-hypergeometric functions.

As with the aforementioned functions, we attempt to derive a generalized differential operator on meromorphic functions in

D^{*} = {z \in C : 0 < | z | < 1}

in this paper and study some of their characteristics.

For complex parameters

γ_{1}, \dots, γ_{d}

and

β_{1}, \dots, β_{s} (β_{t} \neq 0, - 1, \dots; t = 1, 2, \dots, s)

the q-hypergeometric function

_{d} Φ_{s} (z)

is defined by

_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s}; q, z) = \sum_{l = 0}^{\infty} \frac{{(γ_{1}, q)}_{l} \dots {(γ_{d}, q)}_{l}}{{(q, q)}_{l} {(β_{1}, q)}_{l} \dots {(β_{s}, q)}_{l}} \times {[{(- 1)}^{l} q^{(\begin{matrix} l \\ 2 \end{matrix})}]}^{1 + s - d} z^{l},

(8)

with

(\begin{matrix} l \\ 2 \end{matrix}) = l (l - 1) / 2

where

q \neq 0

when

d > s + 1 (d, s \in N_{0} = N \cup \{0\}; z \in D^{*}) .

The q-shifted factorial is defined for

γ, q \in C

as a product of l factors by

{(γ; q)}_{l} = \{\begin{matrix} (1 - γ) (1 - γ q) \dots (1 - γ q^{l - 1}) & (l \in N) \\ 1 & (l = 0) \end{matrix}

(9)

and in terms of basic analogue of the gamma function

{(q^{γ}, q)}_{l} = \frac{Γ_{q} (γ + l) {(1 - q)}^{l}}{Γ_{q} (γ)} l > 0 .

(10)

It is important to note that

{lim}_{q \to - 1} ({(q^{γ}; q)}_{l} / {(1 - q)}^{l}) = {(γ)}_{l} = γ (γ + 1) \dots (γ + l - 1)

is the familiar Pochhammer symbol and

_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s}; z) = \sum_{l = 0}^{\infty} \frac{{(γ_{1})}_{l} \dots {(γ_{d})}_{l}}{{(β_{1})}_{l} \dots {(β_{s})}_{l}} \frac{z^{l}}{l!} .

(11)

Now, for

z \in D, 0 < |q| < 1,

and

d = s + 1

, the basic hypergeometric function defined in (8) takes the form

_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z) = \sum_{l = 0}^{\infty} \frac{{(γ_{1}, q)}_{l} \dots {(γ_{d}, q)}_{l}}{{(q, q)}_{l} {(β_{1}, q)}_{l} \dots {(β_{s}, q)}_{l}} z^{l},

(12)

which converges absolutely in the open disc D.

According to the recently introduced function

_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s}; q, z)

for meromorphic functions

ζ \in ϰ

consisting of functions of the form (1), Al-dweby and Darus [6] developed the q-analogue of the Liu-Srivastava operator, as follows:

\begin{matrix} _{d} Υ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z) * ζ (z) = \frac{1}{z}_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z) * ζ (z) \\ = \frac{1}{z} + \sum_{l = 1}^{\infty} \frac{\prod_{i = 1}^{d} {(γ_{i}, q)}_{l + 1}}{{(q, q)}_{l + 1} \prod_{i = 1}^{s} {(β_{i}, q)}_{l + 1}} a_{l} z^{l}, \end{matrix}

(13)

where

\prod_{n = 1}^{m} {(γ_{n}, q)}_{l + 1} = {(γ_{1}, q)}_{l + 1} {(γ_{2}, q)}_{l + 1} \dots {(γ_{m}, q)}_{l + 1}

, where

z \in D^{*} = {z \in C : 0 < | z | < 1},

and

\begin{matrix} _{d} Υ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z) = \frac{1}{z}_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z) \\ = \frac{1}{z} + \sum_{l = 1}^{\infty} \frac{\prod_{i = 1}^{d} {(γ_{i}, q)}_{l + 1}}{{(q, q)}_{l + 1} \prod_{i = 1}^{s} {(β_{i}, q)}_{l + 1}} z^{l} . \end{matrix}

(14)

Murugusundaramoorthy and Janani [7] defined the following linear operator for functions

ζ \in ϰ_{η}

and for real parameters

γ_{1}, \dots, γ_{d}

and

β_{1}, \dots, β_{s} (β_{t} \neq 0, - 1, \dots; t = 1, 2, \dots, s)

:

_{d} Υ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z - η) : ϰ_{η} \to ϰ_{η},

(15)

\begin{matrix} _{d} Υ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z - η) = \frac{1}{z - η}_{d} Φ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z - η) \\ = \frac{1}{z - η} + \sum_{l = 1}^{\infty} \frac{\prod_{i = 1}^{d} {(γ_{i}, q)}_{l + 1}}{{(q, q)}_{l + 1} \prod_{i = 1}^{s} {(β_{i}, q)}_{l + 1}} {(z - η)}^{l} . \end{matrix}

(16)

Corresponding to the functions

_{d} Υ_{s} (γ_{1}, \dots, γ_{d}; β_{1}, \dots, β_{s},; q, z - η)

and

q_{μ, ξ} (z)

given in (6) and using the Hadamard product for

ζ (z) \in ϰ_{η},

we define a new linear operator

J_{ξ}^{μ} (γ_{1}, γ_{2}, \dots γ_{d}; β_{1}, β_{2}, \dots β_{s}; q)

on

ϰ_{η}

by

J_{ξ}^{μ} (γ_{1}, γ_{2}, \dots γ_{d}; β_{1}, β_{2}, \dots β_{s}; q) ζ (z)

= (ζ (z) *_{d} Υ_{s} (γ_{1}, γ_{2}, \dots γ_{d}; β_{1}, β_{2}, \dots β_{s}; q, z - η) * q_{λ, ξ} (z))

(17)

\begin{matrix} = \frac{1}{z - η} + \sum_{l = 1}^{\infty} \frac{\prod_{i = 1}^{d} {(γ_{i}, q)}_{l + 1}}{{(q, q)}_{l + 1} \prod_{i = 1}^{s} {(β_{i}, q)}_{l + 1}} {(\frac{μ}{l + 1 + μ})}^{ξ} a_{l} {(z - η)}^{l} . \end{matrix}

= \frac{1}{z - η} + \sum_{l = 1}^{\infty} Ω_{s}^{d} (l) a_{l} {(z - η)}^{l},

(18)

where

Ω_{s}^{d} (l) = \frac{\prod_{i = 1}^{d} {(γ_{i}, q)}_{l + 1}}{{(q, q)}_{l + 1} \prod_{i = 1}^{s} {(β_{i}, q)}_{l + 1}} {(\frac{μ}{l + 1 + μ})}^{ξ} .

(19)

For convenience, we will denote

J_{ξ}^{μ} (γ_{1}, γ_{2}, \dots γ_{d}; β_{1}, β_{2}, \dots β_{s}; q) ζ (z) = J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z) .

(20)

In (17), for

ξ = 0

, the operator was investigated by Murugusundaramoorthy and Janani [7].

Recent studies on the meromorphic functions with generalized hypergeometric functions and with q-hypergeometric functions include those by Cho and Kim [8], Dziok and Srivastava [9,10], Ghanim [11], Ghanim et al. [12,13], Liu and Srivastava [14,15], Aldweby and Darus [6], Murugusundaramoorthy and Janani [7]. We define the following new subclass of functions in

ϰ_{η}

using the generalized operator

J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z) .

In response to earlier work on meromorphic functions by function theorists (see [15,16,17,18,19,20,21,22]).

For

0 \leq ν < 1

and

0 \leq ψ \leq 1

, we let

A_{s}^{d} (ψ, τ, ν, η)

indicate a subclass of

ϰ_{η}

that consists of functions of the form (2) that satisfy the requirement that

- ℜ (\frac{(z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{^{'}} + ψ {(z - η)}^{2} {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{''}}{(1 - ψ) J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z) + ψ (z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{'}})

> τ |\frac{(z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{^{'}} + ψ {(z - η)}^{2} {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{''}}{(1 - ψ) J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z) + ψ (z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{'}} + 1| + ν,

(21)

where (17) is used to give

J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z)

.

Additionally, we can state this condition by

- ℜ (\frac{(z - η) F^{^{'}} (z)}{F (z)}) > τ |\frac{(z - η) F^{^{'}} (z)}{F (z)} + 1| + ν,

(22)

where

F (z) = (1 - ψ) J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z) + ψ (z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{'}

= \frac{1 - 2 ψ}{z - η} + \sum_{l = 1}^{\infty} (l ψ - ψ + 1) Ω_{s}^{d} (l) a_{l} {(z - η)}^{l}, a_{l} \geq 0

(23)

where

Ω_{s}^{d} (l)

defind by (18).

It is interesting to note that we can define a number of new subclasses of

ϰ_{η}

by specializing the parameters

ψ, τ

and

d, s

. In the examples that follow, we demonstrate two significant subclasses.

Example 1.

For

ψ = 0

, we let

A_{s}^{d} (0, τ, ν, η) = A_{s}^{d} (τ, ν, η)

indicate a subclass of

ϰ_{η}

that consists of functions of the form (2), which satisfy the requirement that

- ℜ (\frac{(z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{^{'}}}{J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z)}) > τ |\frac{(z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{^{'}}}{J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z)} + 1| + ν,

(24)

where

J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z)

is given by (17).

Example 2.

For

ψ = 0, τ = 0,

we let

A_{s}^{d} (0, 0, ν, η) = A_{s}^{d} (v, η)

indicate a subclass of

ϰ_{η}

that consists of functions of form (2) that satisfy the requirement that

- ℜ (\frac{(z - η) {(J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z))}^{^{'}}}{J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z)}) > ν,

(25)

where

J_{ξ}^{μ} (γ_{d}, β_{s}, q) ζ (z)

is given by (17).

We begin by recalling the following lemma due to Challab, Darus and Ghanim [1].

Lemma 1

([1]). The function

ζ (z)

defined by (2) is in the class in

A_{s}^{d} (ψ, τ, ν, η)

if, and only if,

\sum_{l = 1}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) a_{l} \leq (1 - 2 ψ) (1 - ν) .

(26)

The result is sharp.

In view of Lemma 1, we can see that the function

ζ (z)

, defined by (2) in the class

A_{s}^{d} (ψ, τ, ν, η)

, satisfies the ceofficient inequality

a_{1} \leq \frac{(1 - 2 ψ) (1 - ν)}{[(1 + v + 2 τ)] Ω_{s}^{d} (1)},

(27)

where

Ω_{s}^{d} (1) = \frac{\prod_{i = 1}^{d} {(γ_{i}, q)}_{2}}{{(q, q)}_{2} \prod_{i = 1}^{s} {(β_{i}, q)}_{2}} {(\frac{μ}{μ + 2})}^{ξ} .

Hence we may take

a_{1} = \frac{(1 - 2 ψ) (1 - ν) c}{[((1 + v + 2 τ))] Ω_{s}^{d} (1)} 0 \leq c \leq 1 .

(28)

Making use of (27), we now introduce the following class of functions:

Let

A_{s, c}^{d} (ψ, τ, ν, η)

denote the subclass of

A_{s}^{d} (ψ, τ, ν, η)

, consisting of a function of the form

ζ (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[(1 + ν + 2 τ)] Ω_{s}^{d} (1)} (z - η) + \sum_{l = 2}^{\infty} a_{l} {(z - η)}^{l},

(29)

where

a_{l \geq 0} a n d 0 \leq c \leq 1 .

In this paper, we obtain the coefficient inequalities for the class

A_{s, c}^{d} (ψ, τ, ν, η)

and closure theorems. Further, the radius of convexity are obtained for the class

A_{s, c}^{d} (ψ, τ, ν, η)

.

2. Coefficients’ Inequalities

Theorem 1.

Let the function

ζ (z)

be defined (28). Then,

ζ (z)

is in the class

A_{s, c}^{d} (ψ, τ, ν, η)

if, and only if,

\sum_{l = 2}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) a_{l} \leq (1 - 2 ψ) (1 - ν) (1 - c) .

(30)

The result is sharp.

Proof.

Putting

a_{1} = \frac{(1 - 2 ψ) (1 - ν) c}{[(1 + τ) + (v + τ)] Ω_{s}^{d} (1)} 0 \leq c \leq 1,

(31)

Using (25) and simplification, we arrive at the result, which is sharp for the function

ζ (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[(1 + τ) + (ν + τ)] Ω_{s}^{d} (1)} (z - η) + \frac{(1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} {(z - η)}^{l} (l \geq 2) .

(32)

□

Corollary 1.

Let the function

ζ (z)

defined by (27) be in the class

A_{s, c}^{d} (ψ, τ, ν, η) .

Then,

a_{l} \leq \frac{(1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} (l \geq 2) .

(33)

The result for the function

ζ (z)

given by (31) is sharp.

Corollary 2.

If

0 \leq c_{1} \leq c_{2} \leq 1

A_{s, c_{2}}^{d} (ψ, τ, ν, η) \subseteq A_{s, c_{1}}^{d} (ψ, τ, ν, η) .

3. Closure Theorems

Using Theorem 1, we can prove the following theorems:

Theorem 2.

Let the function

ζ_{j} (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} (z - η) + \sum_{l = 2}^{\infty} a_{l, j} {(z - η)}^{l} (a_{l, j} \geq 0),

(34)

be in the class

A_{s, c}^{d} (ψ, τ, ν, η) .

for every

j = 1, 2, \dots, s .

Then, the function

g (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} (z - η) + \sum_{l = 2}^{\infty} b_{l} {(z - η)}^{l} (b_{l} \geq 0),

(35)

is also in the same class

A_{s, c}^{d} (ψ, τ, ν, η),

where

b_{l} = \frac{1}{m} \sum_{j = 1}^{m} a_{l, j} (l = 1, 2, \dots) .

(36)

Proof.

Since

ζ_{j} (z) \in A_{s, c}^{d} (ψ, τ, ν, η),

it follows from Theorem 1 that

\sum_{l = 2}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) a_{l, j} \leq (1 - 2 ψ) (1 - ν) (1 - c),

(37)

for every

j = 1, 2, \dots, m .

Hence,

\begin{matrix} \sum_{l = 2}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) b_{l} \\ = & \sum_{l = 2}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) (\frac{1}{m} \sum_{j = 1}^{m} a_{l, j}) \end{matrix}

= \frac{1}{m} \sum_{j = 1}^{m} (\sum_{l = 2}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) a_{l, j})

(38)

\begin{matrix} \leq (1 - 2 ψ) (1 - ν) (1 - c) . \end{matrix}

From Theorem 1, it follows that

g (z) \in A_{s, c}^{d} (ψ, τ, ν, η) .

This completes the proof. □

Theorem 3.

The class

A_{s, c}^{d} (ψ, τ, ν, η)

is closed under convex linear combination

Proof.

Let

ζ_{j} (z) (j = 1, 2)

be defined by (33)

h (z) = ϕ ζ_{1} (z) + (1 - ϕ) ζ_{2} (z) (0 \leq ϕ \leq 1),

(39)

It is sufficient to prove that the function h(z) is also in the class

A_{s, c}^{d} (ψ, τ, ν, η) .

Since

h (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} (z - η) + \sum_{l = 2}^{\infty} [ϕ a_{l, 1} + (1 - ϕ) a_{l, 2}] {(z - η)}^{l} .

(40)

Then, we have Theorem 1, that

\begin{matrix} \sum_{l = 2}^{\infty} [l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l) [ϕ a_{l, 1} + (1 - ϕ) a_{l, 2}] \\ \leq ϕ (1 - 2 ψ) (1 - ν) (1 - c) + (1 - ϕ) (1 - 2 ψ) (1 - ν) (1 - c) \\ = (1 - 2 ψ) (1 - ν) (1 - c) . \end{matrix}

Therefore,

h (z) \in A_{s, c}^{d} (ψ, τ, ν, η) .

□

Theorem 4.

Let

ζ (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} (z - η),

(41)

and

ζ_{l} (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} (z - η) + \frac{(1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} {(z - η)}^{l} (l \geq 2) .

(42)

Then,

ζ (z)

is in the class

A_{s, c}^{d} (ψ, τ, ν, η),

if, and only if, it can be expressed in the form

ζ (z) = \sum_{l = 1}^{\infty} λ_{l} ζ_{l} (z),

(43)

where

λ_{l} \geq 0

and

\sum_{l = 1}^{\infty} λ_{l} = 1 .

Proof.

Let

ζ (z) = \sum_{l = 1}^{\infty} λ_{l} ζ_{l} (z),

(44)

= \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ)] Ω_{s}^{d} (1)} (z - η) + \sum_{l = 2}^{\infty} \frac{(1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} λ_{l} {(z - η)}^{l} .

Since

\sum_{l = 2}^{\infty} \frac{(1 - 2 ψ) (1 - ν) (1 - c) λ_{l}}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} . \frac{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)}{(1 - 2 ψ) (1 - ν)}

(45)

= (1 - c) \sum_{l = 2}^{\infty} λ_{l} = (1 - c) (1 - λ_{1}) \leq (1 - c) .

Hence, using Theorem 1, we have

ζ (z) \in A_{s, c}^{d} (ψ, τ, ν, η) .

Conversely, we assume that

ζ (z)

, defined by (28), is in the class

A_{s, c}^{d} (ψ, τ, ν, η) .

Then by applying (32), we can obtain

a_{l} \leq \frac{(1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} (l \geq 2) .

(46)

Setting

λ_{l} = \frac{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)}{(1 - 2 ψ) (1 - ν) (1 - c)} a_{l} (l \geq 2) .

(47)

λ_{1} = 1 - \sum_{l = 2}^{\infty} λ_{l} .

(48)

We have (42). The proof of Theorem 4 is now complete. □

4. Radius of Convexity

Theorem 5.

Let the function

ζ (z)

be defined by (28) in the class

A_{s, c}^{d} (ψ, τ, ν, η) .

Then,

ζ (z)

is meromorphically convex of order

δ (0 \leq δ < 1)

in

0 < |z - η| < r_{1} = r_{1} (ψ, τ, ν, η, c, δ)

where

r_{1} (ψ, τ, ν, η, c, δ),

which has the highest value

\frac{(1 + δ) (1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} r^{2} + \frac{(l (l + 2 - δ) (1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l_{o})} r^{l + 1} \leq (1 - δ),

(49)

for

l \geq 2 .

The result is sharp for the function

ζ_{l} (z) = \frac{1}{z - η} + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} (z - η) + \frac{(1 - 2 ψ) (1 - ν) (1 - c)}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} {(z - η)}^{l},

(50)

for some l.

Proof.

It is sufficient to show that

|\frac{(z - η) ζ^{^{''}} (z)}{ζ^{^{'}} (z)} + 2| \leq 1 - δ (0 \leq δ < 1) for 0 < |z - η| < r_{1} (ψ, τ, ν, η, c, δ) .

Note that

|\frac{(z - η) ζ^{^{''}} (z)}{ζ^{^{'}} (z)} + 2| = |\frac{\frac{2 (1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} {(z - η)}^{2} + \sum_{l = 2}^{\infty} l (l + 1) a_{l} {(z - η)}^{l + 1}}{- 1 + \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} {(z - η)}^{2} + \sum_{l = 2}^{\infty} l a_{l} {(z - η)}^{l + 1}}| \leq 1 - δ

= \frac{\frac{2 (1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} {| z - η |}^{2} + \sum_{l = 2}^{\infty} l (l + 1) a_{l} {| z - η |}^{l + 1}}{1 - (\frac{(1 - 2 ψ) (1 - ν) c}{[(1 + τ) + (ν + τ)] Ω_{s}^{d} (1)} {| z - η |}^{2} + \sum_{l = 2}^{\infty} l a_{l} {| z - η |}^{l + 1})} \leq 1 - δ

\frac{\frac{2 (1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} r^{2} + \sum_{l = 2}^{\infty} l (l + 1) a_{l} r^{l + 1}}{1 - \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} r^{2} - \sum_{l = 2}^{\infty} l a_{l} r^{l + 1}} \leq 1 - δ,

(51)

for

0 < |z - η| < r

if, and only if,

\frac{2 (1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} r^{2} + \sum_{l = 2}^{\infty} l (l + 1) a_{l} r^{l + 1} \leq (1 - δ) (1 - \frac{(1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} r^{2} - \sum_{l = 2}^{\infty} l a_{l} r^{l + 1})

\frac{(3 - δ) (1 - 2 ψ) (1 - ν) c}{[1 + ν + 2 τ] Ω_{s}^{d} (1)} r^{2} + \sum_{l = 2}^{\infty} l (l + 2 - δ) a_{l} r^{l + 1} \leq (1 - δ) .

(52)

Since

ζ (z)

is in the class

A_{s, c}^{d} (ψ, τ, ν, η),

from (32), we may take

a_{l} = \frac{(1 - 2 ψ) (1 - ν) (1 - c) λ_{l}}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)} (l \geq 2),

(53)

where

λ_{l} \geq 0 (l \geq 2)

and

\sum_{l = 1}^{\infty} λ_{l} \leq 1 .

(54)

We select the positive integer

l_{0} = l_{0} (r)

for each fixed r, where

\frac{l (l + 2 - δ) r^{l + 1}}{[l (1 + τ) + (ν + τ)] (1 + l ψ - ψ) Ω_{s}^{d} (l)}

is maximal. Then it follows that

\sum_{l = 2}^{\infty} l (l + 2 - δ) a_{l} r^{l + 1} \leq \frac{(l_{o} (l_{o} + 2 - δ) (1 - 2 ψ) (1 - ν) (1 - c)}{[l_{o} (1 + τ) + (ν + τ)] (1 + l_{o} ψ - ψ) Ω_{s}^{d} (l_{o})} r^{l_{o} + 1} (l \geq 2) .

(55)

Then

ζ (z)

is convex of order

δ

in

0 < |z - η| < r_{1} (ψ, τ, ν, η, c, δ)

provided that

\frac{(3 - δ) (1 - 2 ψ) (1 - ν) c}{[(1 + τ) + (ν + τ)] Ω_{s}^{d} (1)} r^{2} + \frac{(l_{o} (l_{o} + 2 - δ) (1 - 2 ψ) (1 - ν) (1 - c)}{[l_{o} (1 + τ) + (ν + τ)] (1 + l_{o} ψ - ψ) Ω_{s}^{d} (l_{o})} r^{l_{o} + 1} \leq (1 - δ) .

(56)

We find the value

r_{o} = r_{o} (ψ, τ, ν, η, c, δ)

and the corresponding integer

l_{o} (r_{o})

so that

\frac{(3 - δ) (1 - 2 ψ) (1 - ν) c}{[(1 + τ) + (ν + τ)] Ω_{s}^{d} (1)} r_{o}^{2} + \frac{(l_{o} (l_{o} + 2 - δ) (1 - 2 ψ) (1 - ν) (1 - c)}{[l_{o} (1 + τ) + (ν + τ)] (1 + l_{o} ψ - ψ) Ω_{s}^{d} (l_{o})} r_{o}^{l_{o} + 1} = (1 - δ) .

(57)

Then, this value

r_{o}

is the radius of meromorphically convex of order

δ

for functions belonging to the class

A_{s, c}^{d} (ψ, τ, ν, η) .

□

5. Conclusions

The fixed second coefficients of class

A_{s, c}^{d} (ψ, τ, ν, η)

and the q- hypergeometric functions are included in the new class of meromorphic parabolic starlike functions defined in this article. Some features are obtained for the function in the class

A_{s, c}^{d} (ψ, τ, ν, η)

, including the radius of convexity, closure theorems, and coefficient inequalities.

Author Contributions

Investigation, N.S.A.; supervision, N.S.A., A.S. and H.D.; writing—original draft, N.S.A.; writing—review and editing, N.S.A. and H.D. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The first author would like to thank his father Saud Dhaifallah Almutairi for supporting this work.

Conflicts of Interest

The authors declare no conflict of interest.

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Almutairi, N.S.; Shahen, A.; Darwish, H. On Meromorphic Parabolic Starlike Functions with Fixed Point Involving the q-Hypergeometric Function and Fixed Second Coefficients. Mathematics 2023, 11, 2991. https://doi.org/10.3390/math11132991

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Almutairi NS, Shahen A, Darwish H. On Meromorphic Parabolic Starlike Functions with Fixed Point Involving the q-Hypergeometric Function and Fixed Second Coefficients. Mathematics. 2023; 11(13):2991. https://doi.org/10.3390/math11132991

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Almutairi, Norah Saud, Awatef Shahen, and Hanan Darwish. 2023. "On Meromorphic Parabolic Starlike Functions with Fixed Point Involving the q-Hypergeometric Function and Fixed Second Coefficients" Mathematics 11, no. 13: 2991. https://doi.org/10.3390/math11132991

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On Meromorphic Parabolic Starlike Functions with Fixed Point Involving the q-Hypergeometric Function and Fixed Second Coefficients

Abstract

1. Introduction

2. Coefficients’ Inequalities

3. Closure Theorems

4. Radius of Convexity

5. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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