Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator

El-Deeb, Sheza M.; Cotîrlă, Luminiţa-Ioana

doi:10.3390/axioms12020207

Open AccessArticle

Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator

by

Sheza M. El-Deeb

^1,2

and

Luminiţa-Ioana Cotîrlă

^3,*

¹

Department of Mathematics, College of Science and Arts, Al-Badaya, Qassim University, Buraidah 52571, Saudi Arabia

²

Department of Mathematics, Faculty of Science, Damietta University, New Damietta 34517, Egypt

³

Department of Mathematics, Technical University of Cluj-Napoca, 400114 Cluj-Napoca, Romania

^*

Author to whom correspondence should be addressed.

Axioms 2023, 12(2), 207; https://doi.org/10.3390/axioms12020207

Submission received: 23 December 2022 / Revised: 11 February 2023 / Accepted: 14 February 2023 / Published: 15 February 2023

(This article belongs to the Special Issue Recent Advances in Fractional Calculus)

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Abstract

:

In this paper, we define three subclasses

M_{p, α}^{n, q} (η, A, B), I_{p, α}^{n} (λ, μ, γ),

, R

_{p}^{n, q} (λ, μ, γ)

connected with a q-analogue of linear differential operator

D_{α, p, G}^{n, q}

which consist of functions

F

of the form

F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} a_{j} ζ^{j}

(p \in N)

satisfying the subordination condition

p - \frac{1}{η} \{\frac{ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}}}{D_{α, p, G}^{n, q} F (ζ)} + p\} ≺ p \frac{1 + A ζ}{1 + B ζ} .

Also, we study the various properties and characteristics of this subclass

M_{p, α}^{n, q, *} (η, A, B)

such as coefficients estimate, distortion bounds and convex family. Also the concept of

δ

neighborhoods and partial sums of analytic functions to the class

M_{p, α}^{n, q} (η, A, B)

.

Keywords:

fractional derivative; convolution; meromorphic function; q-nalogue of linear differential operator; complex order; q-starlike; q-convex; neighborhoods; partial sums

MSC:

30C50; 30C45; 11B65; 47B38

1. Introduction

Let

M_{p}

is the class of p-valently meromorphic functions of the form:

F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} a_{j} ζ^{j} (p \in N = {1, 2, . . . .}),

(1)

which are analytic in the punctured open unit disk

Δ^{*} : = {ζ \in C : 0 < | ζ | < 1} = Δ ∖ {0} .

Let

F

and

E

are analytic functions in

Δ

, we say that

F

is subordinate to

E

if there exists an analytic function

ϖ (ζ)

with

ϖ (0) = 0

and

|ϖ (ζ)| < 1

(ζ \in Δ)

such that

F = E (ϖ (ζ)) .

We denote by

F ≺ E

(see [1,2]):

Let the functions

F (ζ) \in M_{p}

defined by (1) and

G (ζ) \in M_{p}

defined by

G (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} b_{j} ζ^{j} (p \in N) .

(2)

The Hadamard product or convolution of

F (ζ)

and

G (ζ)

is defined by

(F * G) (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} a_{j} b_{j} ζ^{j} = (G * F) (ζ) .

(3)

In this paper, we define some concepts of fractional derivative, for any non-negative integer j, the

q -

factorial

{[j]}_{q}!

is defined by (see [3]):

Assume that

0 < q < 1,

the q-number

{[j]}_{q}

are defined by (see [3,4,5,6,7,8,9]). where

{[j]}_{q} : = \frac{1 - q^{j}}{1 - q} = 1 + \sum_{r = 1}^{j - 1} q^{r} .

(4)

El-Deeb et al. [10] defined the q-derivative operator for

F * G

as follows (see [11])

D_{q} (F * G) (ζ) : = \{\begin{matrix} \frac{(F * G) (q ζ) - (F * G) (ζ)}{ζ (q - 1)} & ζ \neq 0 \\ F^{'} (0) & ζ = 0 . \end{matrix}

(5)

Also, we have

lim_{q \to 1^{-}} D_{q} (F * G) (ζ) : = lim_{q \to 1^{-}} \frac{(F * G) (q ζ) - (F * G) (ζ)}{ζ (q - 1)} = {((F * G) (ζ))}^{^{'}} .

From (1) and (5), we get

D_{q} (F * G) (ζ) : = - \frac{{[p]}_{q}}{q^{p}} ζ^{- p - 1} + \sum_{j = 1 - p}^{\infty} {[j]}_{q} a_{j} b_{j} ζ^{j - 1}, ζ \neq 0 .

(6)

Also, we define the linear differential operator

D_{α, p, g}^{n, q} : M_{p} \to M_{p}

as follows:

D_{α, p, g}^{0, q} F (ζ) = (F * G) (ζ),

\begin{matrix} D_{α, p, G}^{1, q} F (ζ) & = & \frac{α q^{p}}{{[p]}_{q}} ζ D_{q} (D_{α, p, g}^{0, q} F (ζ)) + (1 - α) (F * G) (ζ) + 2 α ζ^{- p} \\ = & ζ^{- p} + \sum_{j = 1 - p}^{\infty} (\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}}) a_{j} b_{j} ζ^{j} \\ D_{α, p, G}^{2, q} F (ζ) & = & \frac{α q^{p}}{{[p]}_{q}} ζ D_{q} (D_{α, p, g}^{1, q} F (ζ)) + (1 - α) D_{α, p, g}^{1, q} F (ζ) + 2 α ζ^{- p} \\ = & ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{2} a_{j} b_{j} ζ^{j} \\ . \\ . \\ . \\ D_{α, p, G}^{n, q} F (ζ) & = & \frac{α q^{p}}{{[p]}_{q}} ζ D_{q} (D_{α, p, g}^{n - 1, q} F (ζ)) + (1 - α) D_{α, p, g}^{n - 1, q} F (ζ) + 2 α ζ^{- p} \\ = & ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} a_{j} b_{j} ζ^{j} \\ (p \in N, n \in N_{0} = N \cup {0}, 0 < q < 1, α > 0) . \end{matrix}

(7)

From (7), we obtain the following relations:

(i) D_{α, p, G}^{n + 1, q} F (ζ) = \frac{α q^{p}}{{[p]}_{q}} ζ D_{q} (D_{α, p, G}^{n, q} F (ζ)) + (1 - α) D_{α, p, G}^{n, q} F (ζ) + 2 α ζ^{- p}, ζ \in Δ^{*};

(8)

(ii) I_{α, p, G}^{n} F (ζ) : = lim_{q \to 1^{-}} D_{α, p, G}^{n, q} F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{j α + p (1 - α)}{p})}^{n} a_{j} b_{j} ζ^{j}, ζ \in Δ^{*} .

(9)

Remark 1.

(i) By taking

G (ζ) = \frac{ζ^{- p}}{1 - ζ} (

or

b_{j} = 1)

in this operator

D_{α, p, G}^{n, q}

, we have the linear differential operator

D_{α, p, q}^{n}

defined by El-Deeb and El-Matary ([12], With

A = 1

);

(ii) Put

α = 1

in the operator

D_{α, p, G}^{n, q}

, we get the

(p, q)

-analogue of the operator

D_{p, G}^{n, q}

defined as follows:

D_{p, G}^{n, q} F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{q^{p} {[j]}_{q}}{{[p]}_{q}})}^{n} a_{j} b_{j} ζ^{j} (p \in N, n \in N_{0}, 0 < q < 1, ζ \in Δ^{*});

(10)

(iii) Let

α = 1

and

q \to 1

in the operator

D_{α, p, G}^{n, q}

, we have the operator

D_{p, G}^{n}

defined as follows:

D_{p, G}^{n} F (ζ) : = lim_{q \to 1^{-}} D_{1, p, q}^{n} F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{j}{p})}^{n} a_{j} b_{j} ζ^{j}, (p \in N, n \in N_{0}, ζ \in Δ^{*});

(11)

(iv) Taking

α = 1

and

G (ζ) = \frac{ζ^{- p}}{1 - ζ} (

or

b_{j} = 1)

in the operator

D_{α, p, G}^{n, q}

, we have the

(p, q)

-analogue of Salagean operator

D_{p, q}^{n}

defined as follows:

D_{p, q}^{n} F (ζ) : = ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{q^{p} {[j]}_{q}}{{[p]}_{q}})}^{n} a_{j} ζ^{j} (p \in N, n \in N_{0}, 0 < q < 1, ζ \in Δ^{*});

(12)

(v) Putting

q \to 1^{-}

and

α = 1

in the operator

D_{α, p, G}^{n, q}

, we get the operator in meromorphic

D_{p, G}^{n}

defined as follows:

D_{p, G}^{n} F (ζ) : = lim_{q \to 1^{-}} D_{1, p, G}^{n, q} F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} {(\frac{j}{p})}^{n} a_{j} b_{j} ζ^{j}, (p \in N, n \in N_{0}, ζ \in Δ^{*}) .

(13)

A function

F \in M_{p}

is said to be in the subclass

{MS}^{*} (γ)

of meromorphic starlike functions of order

γ

in

Δ^{*},

if it satisfies the following condition (see [13,14,15,16]):

ℜ (\frac{ζ F^{^{'}} (ζ)}{F (ζ)}) < - γ (ζ \in Δ^{*}; 0 \leq γ < 1) .

(14)

A function

F \in M_{p}

is said to be in the subclass

MC (γ)

of meromorphic convex functions of order

γ

in

Δ^{*},

if it satisfies the following condition (see [17]):

ℜ (1 + \frac{ζ F^{^{''}} (ζ)}{F^{^{'}} (ζ)}) < - γ (ζ \in Δ^{*}; 0 \leq γ < 1) .

(15)

It is easy to observe from (14) and (15) that

F \in MC (γ) \Leftrightarrow - ζ F^{^{'}} \in {MS}^{*} (γ) .

(16)

We will generalize these classes by using the new operator

D_{α, p, G}^{n, q},

we define the new class

M_{p, α}^{n, q} (λ, μ, γ)

and study some theorems for this class.

Definition 1.

Assume that

F \in M_{p}

be in the class

M_{p, α}^{n, q} (η, A, B)

if

p - \frac{1}{η} \{\frac{ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}}}{D_{α, p, G}^{n, q} F (ζ)} + p\} ≺ p \frac{1 + A ζ}{1 + B ζ}

(17)

or, equivalently, to

|\frac{{\frac{ζ (D_{α, p, G}^{n, q} F (ζ))}{D_{α, p, G}^{n, q} F (ζ)}}^{^{'}} + p}{B \frac{ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}}}{D_{α, p, G}^{n, q} F (ζ)} + p [(A - B) η + B]}| < 1

(18)

(p \in N, n \in N_{0}, 0 < q < 1, α > 0, η \in C^{*}, - 1 \leq B < A \leq 1, ζ \in Δ^{*}) .

Let

M_{p}^{*}

is subclass of

M_{p}

which contains functions on the form:

F (ζ) : = ζ^{- p} + \sum_{j = p}^{\infty} a_{j} ζ^{j} (p \in N) .

(19)

Also, we can write

M_{p, α}^{n, q, *} (η, A, B) = M_{p, α}^{n, q} (η, A, B) \cap M_{p}^{*} .

Remark 2.

(i) Taking

q \to 1^{-},

we get

lim_{q \to 1^{-}} M_{p, α}^{n, q} (λ, μ, γ) = : I_{p, α}^{n} (λ, μ, γ)

, where

I_{p, α}^{n} (λ, μ, γ)

represents the function

F \in M_{p}

that satisfies (18) for

D_{α, p, G}^{n, q}

replaced with

I_{α, p, G}^{n}

given by (9);

(ii) Putting

α = 1

, we get the subclass R

_{p}^{n, q} (λ, μ, γ)

represents the function

F \in M_{p}

that satisfies (18) for

D_{α, p, G}^{n, q}

replaced with

D_{p, G}^{n, q}

given by (10).

2. Basic Properties of the Subclass $M_{p, α}^{n, q, *}$ (η, A, B)

Theorem 1.

The function

F

defined by (19) belongs to the subclass

M_{p, α}^{n, q, *} (η, A, B)

if and only if

\sum_{j = p}^{\infty} [(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |a_{j}| \leq p |η| (A - B) .

(20)

Proof.

Let (20) holds true, we get

\begin{matrix} |ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}} + p D_{α, p, G}^{n, q} F (ζ)| - |B ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}} + [B p (1 - η) + A p η] D_{α, p, G}^{n, q} F (ζ)| \\ = & |\sum_{j = p}^{\infty} (j + p) {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} a_{j} b_{j} ζ^{j + p}| - \\ |p η (A - B) + \sum_{j = p}^{\infty} [B (j + p) + p η (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} a_{j} b_{j} ζ^{j + p}| \\ \leq & \sum_{j = p}^{\infty} (j + p) {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |a_{j}| r^{j + p} - p η (A - B) \\ - \sum_{j = p}^{\infty} [B (j + p) + p η (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |a_{j}| r^{j + p} \\ = & \sum_{j = p}^{\infty} [(1 - B) (j + p) - p η (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |a_{j}| r^{j + p} - p η (A - B) . \end{matrix}

(21)

Since (21) holds for all

r \in (0, 1) .

Letting

r \to 1^{-},

we obtain

\begin{matrix} |ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}} + p D_{α, p, G}^{n, q} F (ζ)| - |B ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}} + [B p (1 - η) + A p η] D_{α, p, G}^{n, q} F (ζ)| \\ \leq & \sum_{j = p}^{\infty} [(1 - B) (j + p) - p η (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |a_{j}| - p η (A - B) \\ \leq & 0 \end{matrix}

(by (20))

Hence, we get

F (ζ) \in M_{p, α}^{n, q} (η, A, B) .

Conversely, Let

F (ζ)

belongs to

M_{p, α}^{n, q} (η, A, B)

with

F (ζ)

of the form (19), we find from (18), that

|\frac{ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}} + p D_{α, p, G}^{n, q} F (ζ)}{B ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}} + [B p (1 - b) + A p b] D_{α, p, G}^{n, q} F (ζ)}|

= |\frac{\sum_{j = p}^{\infty} (j + p) {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} a_{j} b_{j} ζ^{j + p}}{p η (A - B) + \sum_{j = p}^{\infty} [B (j + p) + p η (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} a_{j} b_{j} ζ^{j + p}}| < 1 .

(22)

Using the fact that

ℜ \{ζ\} \leq |ζ|

for all

ζ,

we get

ℜ \{\frac{\frac{ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}}}{D_{α, p, G}^{n, q} F (ζ)} + p}{\frac{B ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}}}{D_{α, p, G}^{n, q} F (ζ)} + [B p (1 - η) + A p η]}\} < 1, ζ \in Δ^{*} .

(23)

If we take

ζ

on real axis, so that

\frac{ζ {(D_{α, p, G}^{n, q} F (ζ))}^{^{'}}}{D_{α, p, G}^{n, q} F (ζ)}

is real. Upon clearing the denominator in (23) and letting

ζ \to 1^{-}

, we get

\sum_{j = p}^{\infty} [(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |a_{j}| \leq p |η| (A - B),

(24)

which we’ve got the assertion (20) of Theorem 1. □

Corollary 1.

The function

F (ζ)

be defined by (19) belongs to

M_{p, α}^{n, q, *} (η, A, B)

, then

|a_{j}| \leq \frac{p |η| (A - B)}{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}} (j \geq p) .

(25)

This result is sharp for

F

given by

F (ζ) = ζ^{- p} + \frac{p |η| (A - B)}{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}} ζ^{j} (j \geq p) .

(26)

Theorem 2.

The function

F (ζ)

defined by (19) belongs

M_{p, α}^{n, q, *} (η, A, B),

then for

|ζ| = r < 1

, we have

\begin{matrix} \{\frac{(p + m - 1)!}{(p - 1)!} - \frac{p! |η| (A - B)}{[2 (1 - B) - |η| (A - B)] {(1 + α (q^{p} - 1))}^{n} (p - m)! b_{p}} r^{2 p}\} r^{- (p + m)} \\ \leq |F^{(m)} (ζ)| \leq \{\frac{(p + m - 1)!}{(p - 1)!} + \frac{p! |η| (A - B)}{[2 (1 - B) - |η| (A - B)] {(1 + α (q^{p} - 1))}^{n} (p - m)! b_{p}} r^{2 p}\} r^{- (p + m)} . \end{matrix}

(27)

This result is sharp for

F

given by

F (ζ) = ζ^{- p} + \frac{|η| (A - B)}{[2 (1 - B) - |η| (A - B)] {(1 + α (q^{p} - 1))}^{n} b_{p}} ζ^{p} .

(28)

Proof.

Let

F (ζ) \in M_{p, α}^{n, q, *} (η, A, B),

then

\begin{matrix} \frac{p [2 (1 - B) - |η| (A - B)] {(1 + α (q^{p} - 1))}^{n} (p - m)! b_{p}}{p!} \sum_{j = p}^{\infty} \frac{j!}{(j - m)!} |a_{j}| \\ \leq & \sum_{j = p}^{\infty} [(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} . |a_{j}| \leq p |η| (A - B), \end{matrix}

which yields

\sum_{j = p}^{\infty} \frac{j!}{(j - m)!} |a j| \leq \frac{|η| (A - B)}{[2 (1 - B) - |η| (A - B)] {(1 + α (q^{p} - 1))}^{n} b_{p}} \frac{p!}{(p - m)!} .

(29)

Differentiating both sides of (19) m times with respect to

ζ

, we get

F^{(m)} (ζ) = {(- 1)}^{m} \frac{(p + m - 1)!}{(p - 1)!} ζ^{- (p + m)} + \sum_{j = p}^{\infty} \frac{j!}{(j - m)!} |a_{j}| ζ^{j - m} (p \in N, 0 \leq m < p)

(30)

and Theorem 2 follows easily from (29) and (30), and it is easy to have the bounds in (27) are attained for

F

given by (28). □

Theorem 3.

The function

F

defined by (19) belings to

M_{p, α}^{n, q, *} (η, A, B),

then

(i)

F

is meromorphically p-valent q-starlike of order ρ

(0 \leq ρ < {[p]}_{q})

in the disc

|ζ| < r_{1},

that is,

ℜ \{- \frac{ζ D_{q} F (ζ)}{F (ζ)}\} > ρ (|ζ| < r_{1}, 0 \leq ρ < {[p]}_{q}, p \in N),

(31)

where

r_{1} = inf_{j \geq p} {\{\frac{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n}}{p |η| (A - B)} \frac{(\frac{{[p]}_{q}}{q^{p}} - ρ) b_{j}}{({[j]}_{q} + ρ)}\}}^{\frac{1}{j + p}},

(32)

(ii)

F

is meromorphically p-valent q-convex of order ρ

(0 \leq ρ < {[p]}_{q})

in the disc

|ζ| < r_{2},

that is,

ℜ \{- (\frac{D_{q} (ζ D_{q} F (ζ))}{D_{q} F (ζ)})\} > ρ (|ζ| < r_{2}, 0 \leq ρ < {[p]}_{q}, p \in N),

(33)

where

r_{2} = inf_{j \geq p} {\{\frac{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} (\frac{{[p]}_{q}}{q^{p}} - ρ) {[p]}_{q} b_{j}}{p q^{p} {[j]}_{q} ({[j]}_{q} + ρ) |η| (A - B)}\}}^{\frac{1}{j + p}} .

(34)

Each of these results is sharp for the function

F (ζ)

given by (26).

Proof .

(i) From the definition (19), we easily get

|\frac{\frac{ζ D_{q} F (ζ)}{F (ζ)} + \frac{{[p]}_{q}}{q^{p}}}{\frac{ζ D_{q} F (ζ)}{F (ζ)} - \frac{{[p]}_{q}}{q^{p}} + 2 ρ}| \leq \frac{\sum_{j = p}^{\infty} ({[j]}_{q} + \frac{{[p]}_{q}}{q^{p}}) |a_{j}| {|ζ|}^{j + p}}{2 (\frac{{[p]}_{q}}{q^{p}} - ρ) - \sum_{j = p}^{\infty} ({[j]}_{q} - \frac{{[p]}_{q}}{q^{p}} + 2 ρ) |a_{j}| {|ζ|}^{j + p}} .

(35)

We have the inequality

|\frac{\frac{ζ D_{q} F (ζ)}{F (ζ)} + \frac{{[p]}_{q}}{q^{p}}}{\frac{ζ D_{q} F (ζ)}{F (ζ)} - \frac{{[p]}_{q}}{q^{p}} + 2 ρ}| \leq 1 (0 \leq ρ < {[p]}_{q}; p \in N),

(36)

if

\sum_{j = p}^{\infty} (\frac{{[j]}_{q} + ρ}{\frac{{[p]}_{q}}{q^{p}} - ρ}) |a_{j}| {|ζ|}^{j + p} \leq 1 .

(37)

Hence, by Theorem 1, (37) will be true

\frac{({[j]}_{q} + ρ)}{(\frac{{[p]}_{q}}{q^{p}} - ρ)} {|ζ|}^{j + p} \leq \frac{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}}{p |η| (A - B)}

|ζ| \leq {\{\frac{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}}{p |η| (A - B)} \frac{(\frac{{[p]}_{q}}{q^{p}} - ρ)}{({[j]}_{q} + ρ)}\}}^{\frac{1}{j + p}},

(38)

the inequality leads us immediately to the disc

|ζ| < r_{1},

where

r_{1}

is given by (32).

(ii) To prove the second assertion of Theorem 3, we get from the definition (19) that

|\frac{\frac{D_{q} (ζ D_{q} F (ζ))}{D_{q} F (ζ)} + \frac{{[p]}_{q}}{q^{p}}}{\frac{D_{q} (ζ D_{q} F (ζ))}{D_{q} F (ζ)} - \frac{{[p]}_{q}}{q^{p}} + 2 ρ}| \leq \frac{\sum_{j = p}^{\infty} {[j]}_{q} ({[j]}_{q} + \frac{{[p]}_{q}}{q^{p}}) |a_{j}| {|ζ|}^{j + p}}{2 \frac{{[p]}_{q}}{q^{p}} (\frac{{[p]}_{q}}{q^{p}} - ρ) - \sum_{j = p}^{\infty} {[j]}_{q} ({[j]}_{q} - \frac{{[p]}_{q}}{q^{p}} + 2 ρ) |a_{j}| {|ζ|}^{j + p}} .

(39)

Thus, we have the desired inequality

|\frac{\frac{D_{q} (ζ D_{q} F (ζ))}{D_{q} F (ζ)} + \frac{{[p]}_{q}}{q^{p}}}{\frac{D_{q} (ζ D_{q} F (ζ))}{D_{q} F (ζ)} - \frac{{[p]}_{q}}{q^{p}} + 2 ρ}| \leq 1 (0 \leq ρ < {[p]}_{q}, p \in N),

(40)

if

\sum_{j = p}^{\infty} \frac{q^{p} {[j]}_{q}}{{[p]}_{q}} (\frac{{[j]}_{q} + ρ}{\frac{{[p]}_{q}}{q^{p}} - ρ}) |a_{j}| {|ζ|}^{j + p} \leq 1 .

(41)

From Theorem 1, (41) will be true if

\frac{q^{p} {[j]}_{q}}{{[p]}_{q}} (\frac{{[j]}_{q} + ρ}{\frac{{[p]}_{q}}{q^{p}} - ρ}) {|ζ|}^{j + p} \leq \frac{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}}{p |η| (A - B)} .

(42)

The inequality (42) readily yields the disc

|ζ| < r_{2},

where

r_{2}

defined by (34), and the proof of Theorem 3 is completed. □

3. Neighborhoods and Partial Sums

By following the earlier works based upon the familiar concept of neighborhoods of analytic functions by Goodman [15] and Ruscheweyh [18] and (more recently) by Altintas et al. [19,20,21], Liu [22], Liu and Srivastava [23] and El-Ashwah et al. [24], we introduce here the

δ

-neighborhoods of a function

F \in M_{p}

has the form (1) by means of the definition given by:

\begin{matrix} N_{δ} (F) & = \{h : h \in M_{p}, h (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} c_{j} z^{j} and \\ \sum_{j = 1 - p}^{\infty} \frac{[(j + p) (1 - B) - p |η| (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}}{p |η| (A - B)} |c_{j} - a_{j}| \leq δ \\ {\begin{matrix} (n \in N_{0}, 0 < q < 1, α > 0, η \in C^{*}, - 1 \leq B < A \leq 1) \end{matrix}}_{\begin{matrix}  \end{matrix}}^{\begin{matrix}  \end{matrix}}\} . \end{matrix}

(43)

Using the definition (43), we will obtain the following theorem:

Theorem 4.

The function

F

defined by (1) belongs to

M_{p, α}^{n, q} (η, A, B)

. If

F

satisfies the condition

\frac{F (ζ) + ϵ ζ^{- p}}{1 + ϵ} \in M_{p, α}^{n, q} (η, A, B) (ϵ \in C, |ϵ| < δ, δ > 0)

(44)

then

N_{δ} (F) \subset M_{p, α}^{n, q} (η, A, B) .

(45)

Proof.

From (18), we obtain

h \in M_{p, α}^{n, q} (η, A, B)

if, for

σ \in C

with

|σ| = 1,

we have

\frac{ζ {(D_{α, p, G}^{n, q} h (ζ))}^{^{'}} + p D_{α, p, G}^{n, q} h (ζ)}{B ζ {(D_{α, p, G}^{n, q} h (ζ))}^{^{'}} + [B p (1 - b) + A p b] D_{α, p, G}^{n, q} h (ζ)} \neq σ (ζ \in Δ),

(46)

which is equivalent to

\frac{(h * ψ) (ζ)}{ζ^{- p}} \neq 0 (ζ \in Δ^{*}),

(47)

where, for convenience,

\begin{matrix} ψ (ζ) & = ζ^{- p} + \sum_{j = 1 - p}^{\infty} y_{j} ζ^{j} \\ = ζ^{- p} + \sum_{j = 1 - p}^{\infty} \frac{[(j + p) (1 - B σ) - p |η| σ (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}}{p η σ (A - B)} ζ^{j} . \end{matrix}

(48)

From (48), we get

\begin{matrix} |y_{j}| & = |\frac{[(j + p) (1 - B σ) - p |η| σ (A - B)] {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}}{p η σ (A - B)}| \\ \leq \frac{[(j + p) (1 + |B|) - p |η| (A - B)]}{p |η| (A - B)} {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} (j \geq p, p \in N) . \end{matrix}

(49)

If

F (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} a_{j} ζ^{j} \in M_{p}

holds the condition (44), then (47) yields

|\frac{(F * ψ) (ζ)}{ζ^{- p}}| > δ (ζ \in Δ^{*}, δ > 0) .

(50)

Let

Φ (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{\infty} d_{j} ζ^{j} \in N_{δ} (F)

(51)

we have

|\frac{[Φ (ζ) - F (ζ)] * ψ (ζ)}{ζ^{- p}}| = |\sum_{j = 1 - p}^{\infty} (d_{j} - a_{j}) y_{j} ζ^{j + p}|

\begin{matrix} \leq |ζ| \sum_{j = 1 - p}^{\infty} \frac{[(j + p) (1 + |B|) - p |η| (A - B)]}{p |η| (A - B)} {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j} |d_{j} - a_{j}| \\ < δ (ζ \in Δ, δ > 0) . \end{matrix}

(52)

We have (47), and hence also (46) for any

σ,

which implies that

Φ \in M_{p, α}^{n, q} (η, A, B) .

This evidently proves the assertion (45) of Theorem 4. □

Theorem 5.

Let

F \in M_{p}

defined by (1) and

- 1 \leq B \leq 0,

the partial sums

S_{1} (ζ)

and

S_{m} (ζ)

are given by

S_{1} (ζ) = ζ^{- p} a n d S_{m} (ζ) = ζ^{- p} + \sum_{j = 1 - p}^{m - 1} a_{j} ζ^{j} (m \in N ∖ {1}) .

(53)

Also, suppose that

\sum_{j = 1 - p}^{\infty} y_{j + p} |a_{j}| \leq 1 (y_{j + p} = \frac{[(j + p) (1 + |B|) - p |η| (A - B)]}{p |η| (A - B)} {(\frac{α q^{p} {[j]}_{q} + (1 - α) {[p]}_{q}}{{[p]}_{q}})}^{n} b_{j}),

(54)

then

(i) F (ζ) \in M_{p, α}^{n, q} (η, A, B)

(ii) R e \{\frac{F (ζ)}{S_{m} (ζ)}\} > 1 - \frac{1}{y_{q}} (ζ \in Δ, m \in N)

(55)

and

(iii) R e \{\frac{S_{m} (ζ)}{F (ζ)}\} > \frac{y_{q}}{1 + y_{q}} (ζ \in Δ, m \in N) .

(56)

The estimates in (55) and (56) are sharp.

Proof.

Since

\frac{ζ^{- p} + ε ζ^{- p}}{1 + ε} = ζ^{- p} \in M_{p, α}^{n, q} (η, A, B),

|ε| < 1,

then by Theorem 4, we have

N_{δ} (F) \subset M_{p, α}^{n, q} (η, A, B),

p \in N .

N_{1} (ζ^{- p})

denoting the 1-neighbourhood). Now since

\sum_{j = 1 - p}^{\infty} y_{j} |a_{j}| \leq 1,

(57)

then

F \in N_{1} (ζ^{- p})

and

F \in M_{p, α}^{n, q} (η, A, B) .

Since

\{y_{j}\}

is an increasing sequence, we get

\sum_{j = 1 - p}^{m - p - 1} |a_{j}| + y_{m} \sum_{j = m - p}^{\infty} |a_{j}| \leq \sum_{j = 1 - p}^{\infty} y_{j + p} |a_{j}| \leq 1,

(58)

we have used the hypothesis (54). Putting

h_{1} (ζ) = y_{m} \{\frac{F (ζ)}{S_{m} (ζ)} - (1 - \frac{1}{y_{m}})\} = 1 + \frac{y_{m} \sum_{j = m - p}^{\infty} |a_{j}| ζ^{j + p}}{1 + \sum_{j = 1 - p}^{m - p - 1} |a_{j}| ζ^{j + p}}

and applying (58), we find that

|\frac{h_{1} (ζ) - 1}{h_{1} (ζ) + 1}| \leq \frac{y_{m} \sum_{j = m - p}^{\infty} |a_{j}|}{2 - 2 \sum_{j = 1 - p}^{m - p - 1} |a_{j}| - y_{m} \sum_{j = m - p}^{\infty} |a_{j}|} \leq 1 (ζ \in Δ),

(59)

which readily yields the assertion (55) of Theorem 5. If we take

F (ζ) = ζ^{- p} - \frac{ζ^{m}}{y_{m}},

(60)

then

\frac{F (ζ)}{S_{m} (ζ)} = 1 - \frac{ζ^{p + m}}{y_{m}} \to 1 - \frac{1}{y_{m}}, as ζ \to 1^{-},

which shows that the bound in (55) is the best possible for each

m \in N .

If we put

h_{2} (ζ) = (1 + y_{m}) \{\frac{S_{m} (ζ)}{F (ζ)} - \frac{y_{m}}{1 + y_{m}}\} = 1 - \frac{(1 + y_{m}) \sum_{j = m - p}^{\infty} |a_{j}| ζ^{j + p}}{1 + \sum_{j = 1 - p}^{\infty} |a_{j}| ζ^{j + p}},

(61)

and make use of (58), we can deduce that

|\frac{h_{2} (ζ) - 1}{h_{2} (ζ) + 1}| \leq \frac{(1 + y_{m}) \sum_{j = m - p}^{\infty} |a_{j}|}{2 - 2 \sum_{j = 1 - p}^{m - p - 1} |a_{j}| - (1 - y_{m}) \sum_{j = m - p}^{\infty} |a_{j}|} \leq 1,

leads us to the assertion (56) of Theorem 5. The bound in (56) is sharp. The proof of Theorem 5 is completed. □

4. Concluding Remarks and Observations

In our present investigation, we have introduced and studied the properties of some new subclasses of the class of meromorphic p-valent functions in the open unit disk

Δ^{*}

by using the combination of q-derivative and convolution and obtain the new operator

D_{α, p, g}^{n, q}

. Among other properties and results such as coefficients estimate, distortion bounds and convex family. Also the concept of

δ

neighborhoods and partial sums of analytic functions to the class

M_{p, α}^{n, q} (η, A, B)

.

Interesting results about meromorphic functions can be found in the works [25,26,27,28,29,30,31].

Author Contributions

Conceptualization, S.M.E.-D. and L.-I.C.; methodology, S.M.E.-D. and L.-I.C.; software, S.M.E.-D. and L.-I.C.; validation, S.M.E.-D. and L.-I.C.; formal analysis, S.M.E.-D. and L.-I.C.; investigation, S.M.E.-D. and L.-I.C.; resources, S.M.E.-D. and L.-I.C.; data curation, S.M.E.-D. and L.-I.C.; writing—original draft preparation, S.M.E.-D. and L.-I.C.; writing—review and editing, S.M.E.-D. and L.-I.C.; visualization, S.M.E.-D. and L.-I.C.; supervision, S.M.E.-D. and L.-I.C.; project administration, S.M.E.-D. and L.-I.C.; funding acquisition, L.-I.C. 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.

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El-Deeb, S.M.; Cotîrlă, L.-I. Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator. Axioms 2023, 12, 207. https://doi.org/10.3390/axioms12020207

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El-Deeb SM, Cotîrlă L-I. Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator. Axioms. 2023; 12(2):207. https://doi.org/10.3390/axioms12020207

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El-Deeb, Sheza M., and Luminiţa-Ioana Cotîrlă. 2023. "Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator" Axioms 12, no. 2: 207. https://doi.org/10.3390/axioms12020207

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Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator

Abstract

1. Introduction

2. Basic Properties of the Subclass $M_{p, α}^{n, q, *}$ (η, A, B)

3. Neighborhoods and Partial Sums

4. Concluding Remarks and Observations

Author Contributions

Funding

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Conflicts of Interest

References

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Basic Properties for Certain Subclasses of Meromorphic p-Valent Functions with Connected q-Analogue of Linear Differential Operator

Abstract

1. Introduction

2. Basic Properties of the Subclass M p , α n , q , ∗ (η, A, B)

3. Neighborhoods and Partial Sums

4. Concluding Remarks and Observations

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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2. Basic Properties of the Subclass $M_{p, α}^{n, q, *}$ (η, A, B)