Jackson Differential Operator Associated with Generalized Mittag–Leffler Function

Attiya, Adel A.; Yassen, Mansour F.; Albaid, Abdelhamid

doi:10.3390/fractalfract7050362

Open AccessArticle

Jackson Differential Operator Associated with Generalized Mittag–Leffler Function

by

Adel A. Attiya

^1,2,*

,

Mansour F. Yassen

^3,4

and

Abdelhamid Albaid

⁵

¹

Department of Mathematics, College of Science, University of Ha’il, Ha’il 81451, Saudi Arabia

²

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

³

Department of Mathematics, College of Science and Humanities in Al-Aflaj, Prince Sattam Bin Abdulaziz University, Al-Aflaj 11912, Saudi Arabia

⁴

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

⁵

Department of Physics, College of Science, University of Ha’il, Ha’il 81451, Saudi Arabia

^*

Author to whom correspondence should be addressed.

Fractal Fract. 2023, 7(5), 362; https://doi.org/10.3390/fractalfract7050362

Submission received: 19 March 2023 / Revised: 24 April 2023 / Accepted: 24 April 2023 / Published: 28 April 2023

(This article belongs to the Special Issue Fractional Operators and Their Applications)

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Abstract

:

Quantum calculus plays a significant role in many different branches such as quantum physics, hypergeometric series theory, and other physical phenomena. In our paper and using quantitative calculus, we introduce a new family of normalized analytic functions in the open unit disk, which relates to both the generalized Mittag–Leffler function and the Jackson differential operator. By using a differential subordination virtue, we obtain some important properties such as coefficient bounds and the Fekete–Szegő problem. Some results that represent special cases of this family that have been studied before are also highlighted.

Keywords:

Mittag–Leffler function; Jackson differential operator; quantum calculus; analytic functions; univalent functions; subordination relation; differential subordination; operators in geometric function theory; Fekete–Szegő function; Gaussian hypergeometric function

MSC:

30C45; 30C80; 30C50; 05A30; 33E12; 33C05

1. Introduction

First, let us assume that

Δ

represents a family of analytic functions as the form below

u (η) = η + \sum_{k = 2}^{\infty} a_{k} η^{k}, η \in D,

(1)

where

D

represents the set of all values

η

in the open unit disk

η \in C

satisfying

| η | < 1

.

The Hadamard product of both functions

u_{1} (η) = η + \sum_{k = 2}^{\infty} a_{k} η^{k}

and

u_{2} = η + \sum_{k = 2}^{\infty} b_{k} η^{k}

in

Δ

is defined by (see [1])

(u_{1} * u_{2}) (η) = η + \sum_{k = 2}^{\infty} a_{k} b_{k} η^{k}, η \in D .

For the analytic functions

u_{1}

and

u_{2}

(u_{1}, u_{2} \in D)

, the function

u_{1}

is called subordinate to the function

u_{2}

, and it is written

u_{1} (η) ≺ u_{2} (η)

; if we have a function

ω

(Schwarz function), which is analytic in the open disk

D

with the conditions

ω (0) = 0

and

|ω (η)| < 1

,

η \in D

satisfies

u_{1} (η) = u_{2} (ω (η))

for all

η \in D

. If the function

u_{2} \in S

(the class of univalent functions in

D)

, then (cf., e.g., [2,3])

u_{1} (η) ≺ u_{2} (η) \Leftrightarrow u_{1} (0) = u_{2} (0) and u_{1} (D) \subset u_{2} (D) .

The Geometric Function Theory (GFT) is an important branch of the field of complex analysis, which is concerned with the study of many important geometric properties in complex analysis, which are related to analytic functions and have numerous applications in different fields, such as analytic number theory, dynamical systems, and fractal calculus. It also has many applications in special functions and probability distributions as well as in fuzzy algebra and other fields.

There are many classes of normalized functions which appear simultaneously with studying GFT, e.g.,

A function

u (η) \in

Δ

belongs to the class of starlike functions

S^{*}

if it satisfies

Re (\frac{η u^{^{'}} (η)}{u (η)}) > 0 (η \in D),

and a function

u (η) \in

Δ

belongs to the class of starlike functions of order

υ

denoted by

S^{*} (υ)

if it satisfies

Re (\frac{η u^{^{'}} (η)}{u (η)}) > υ (η \in D),

for

υ (0 \leq υ < 1) .

In addition, a function

u (η) \in

Δ

belongs to the class of convex functions

C^{*}

if it satisfies

Re (1 + \frac{η u^{″} (η)}{u^{^{'}} (η)}) > 0 (η \in D),

and a function

u (η) \in

Δ

belongs to the class of convex functions of order

υ

denoted by

C^{*} (υ)

if it satisfies

Re (1 + \frac{η u^{″} (η)}{u^{^{'}} (η)}) > υ (η \in D),

for some

υ (0 \leq υ < 1) .

For more details of the classes

S^{*}

,

S^{*} (υ)

,

C^{*}

and

C^{*} (υ)

, see, e.g., Robertson [4], Bulboaca [2], Miller and Mocanu [5] and Duren [3].

Moreover, a function

u (η) \in

Δ

is said to be in the class C if it satisfies

Re (\frac{u (η)}{η}) > 0 (η \in D),

and

u (η) \in

Δ

belongs to the class

C (υ)

if it satisfies

Re (\frac{u (η)}{η}) > υ (η \in D),

for

υ (0 \leq υ < 1),

the classes C and

C (υ)

were studied by MacGregor [6] and Èzrohi [7], respectively.

Furthermore, a function

u (η)

∈

Δ

belongs to the class

B

if it satisfies

Re (u^{^{'}} (η)) > 0 (η \in D),

and the function

u (η)

∈

Δ

belongs to the class

B (υ)

if it satisfies

Re (u^{^{'}} (η)) > υ (η \in D),

for some

υ (0 \leq υ < 1) .

The class

B

was studied by Goel [8] and Yamaguchi [9]. In addition, the class

B (υ)

was studied by Chen [10,11] and Goel [12]; see also [13].

Furthermore, let

R : = \{P : P (η) = \sum_{k = 0}^{\infty} b_{k} η^{k}, b_{0} = 1, Re P (η) > 0 (b_{0} = 1, η \in D)\},

denote all the Carathéodory functions (see [14,15]).

Quantum calculus plays a significant role in the quantum physics and hypergeometric series theory as well as other physical phenomena. The applications of q-differentiation and also q-integration were defined and introduced by Jackson [16,17]; see also [18,19,20,21,22,23,24].

The Mittag–Leffler function

E_{α} (η)

(η \in C)

was obtained by Mittag–Leffler [25,26] which in the form

\begin{matrix} E_{α} (η) = \sum_{k = 0}^{\infty} \frac{η^{k}}{Γ (α k + 1)}, \\ (α \in C; Re (α) > 0) . \end{matrix}

Wiman [27] introduced Wim’s function

E_{α, β} (η)

(η \in C)

in the form

E_{α, β} (η) = \sum_{k = 0}^{\infty} \frac{η^{k}}{Γ (α k + β)},

where

α

and

β

are complex values in

C

,

Re (α) > 0

and

Re (β) > 0 .

Prabhakar [28] introduced the function

E_{α, β}^{δ} (η)

(η \in C)

in the form

\begin{matrix} E_{α, β}^{δ} (η) = \sum_{k = 0}^{\infty} \frac{{(δ)}_{k} η^{k}}{Γ (α k + β) k!}, \\ (α, β, δ & \in C; Re (α) > 0; Re (β) > 0; Re (δ) > 0), \end{matrix}

where

{(δ)}_{n}

is the Pochhammer symbol:

{(δ)}_{n} = \frac{Γ (δ + n)}{Γ (δ)} = \{\begin{matrix} 1, n = 0 \\ δ (δ + 1) \dots (δ + n - 1) \end{matrix} .

(2)

For the Mittag–Leffler function and related articles, see for example [29,30,31,32,33,34].

Raina’s function ([35]; see also [18]) is defined by

_{N} H_{a, b} (η) = \sum_{k = 0}^{\infty} \frac{N (k)}{Γ (a k + b)} η^{k}, η \in D,

where a and

b

are complex values in

C

,

Re (a) > 0

and

Re (b) > 0

and the sequence

{\{N (k)\}}_{k \in N_{0}}

is bounded

(N (k) \in C)

.

Remark 1.

1.: If $N (k) = 1$ $(k \geq 0)$ , then Raina’s function gives the Mittag–Leffler function.
2.: If ${(n)}_{k}$ is the well-known Pochhammer symbol, $N (k) = \frac{{(a)}_{k} {(b)}_{k}}{{(c)}_{k}}, a = 1$ and $b = 1$ , then Raina’s function reduces to the following Gaussian hypergeometric function:

$_{2} F_{1} (a, b; c; η) = \sum_{k = 0}^{\infty} \frac{{(a)}_{k} {(b)}_{k}}{{(c)}_{k}} \frac{η^{k}}{Γ (k + 1)}, η \in D .$

Definition 1

([16]). The Jackson derivative of

u (η)

is defined as follows

(d_{l}) u (η) : = \frac{u (η) - u (l η)}{η (1 - l)}, (0 < l < 1) .

Therefore,

d_{q} (η^{k}) = \frac{1 - l^{k}}{1 - l} η^{k - 1}, k \in N \cup {0},

when

u (η)

has the form (1), then we have

(d_{q}) u (η) = 1 + \sum_{k = 2}^{\infty} a_{k} {[k]}_{q} η^{k - 1},

where

{[k]}_{l} : = \frac{1 - l^{k}}{1 - l} .

In addition, note that

d_{l} κ = 0 and lim_{l \to 1^{-}} (d_{l}) u (η) = u^{'} (η),

where

κ

is a constant in

C

.

When

s \in C

, then the q-shifted factorial denoted by

{(s; q)}_{τ}

is defined as follows (see [16])

{(s; q)}_{τ} : = \prod_{j = 0}^{τ - 1} (1 - q^{j} s), τ \in N : = {1, 2, \dots}, {(s; q)}_{0} = 1 .

(3)

By using (3), we can formulate q-shifted gamma function as follows:

{(q^{t}; q)}_{τ} = \frac{Γ (s + τ) {(1 - q)}^{τ}}{Γ_{q} (s)} (t \in N)

where

Γ_{q} (s) = \frac{{(q; q)}_{\infty} {(1 - q)}^{1 - s}}{{(q^{s}; q)}_{\infty}} (0 < q < 1)

and

{(s; q)}_{\infty} = \prod_{j = 0}^{\infty} (1 - q^{j} s) .

In geometric function theory, there are many famous operators dealing with normalized functions, e.g.,

Let

D^{α}

be a differential operator

D^{α} : Δ \to Δ

defined as follows

D^{α} u (η) = \frac{η}{{(1 - η)}^{α + 1}} * u (η) (α > - 1),

D^{α}

represents Ruscheweyh derivatives as defined by Ruscheweyh [36], which can be in the form

D^{α} u (η) = η + \sum_{k = 2}^{\infty} \frac{{(α - 1)}_{k - 1}}{(k - 1)!} a_{k} η^{k}, η \in D, (α > - 1),

where

{(α)}_{k}

denotes the Pochhammer symbol defined by (2).

In addition, for

u (η) \in Δ

and

η \in D,

the following integral operators

A (u), L (u)

and

L_{γ} (u)

are defined as

A (u) (η) = \int_{0}^{η} \frac{u (t)}{t} d t,

L (u) (η) = \frac{2}{η} \int_{0}^{η} u (t) d t

and

L_{γ} (u) (η) = \frac{1 + γ}{η^{γ}} \int_{0}^{η} u (t) t^{γ - 1} d t (γ > - 1) .

The operators

A (u)

and

L (u)

are the Alexander operator and Libera operator, which were introduced by Alexander [37] and Libera [38], respectively.

L_{γ} (u)

represents a generalized Bernardi operator; the operator

L_{γ} (u)

when

γ \in N = {1, 2, \dots}

was introduced by Bernardi [39].

Moreover, Jung et al. [40] introduced the following integral operator:

I^{σ} (u) (η) = \frac{2^{σ}}{η Γ (σ)} \int_{0}^{η} {(log (\frac{η}{t}))}^{σ - 1} u (t) d t (σ > 0, u (η) \in Δ),

they showed that

I^{σ} (u) (η) = η + \sum_{k = 2}^{\infty} {(\frac{2}{k + 1})}^{σ} a_{k} η^{k} .

The operator

I^{σ} (u)

is closely related to multiplier transformations studied earlier by Flett [41].

Furthermore, denote by

J_{s, b} (u) : Δ \to Δ

the Srivastava–Attiya operator, which is introduced by Srivastava and Attiya [42]; see also ([43]) defined by

J_{s, b} (u) (η) = G_{s, b} (η) = {(1 + b)}^{s} [φ (η, s, b) - b^{- s}] * u (η) (η \in D),

where

φ (η, s, b)

is the general Hurwitz–Lerch–Zeta function defined by (cf., e.g., ([44], p. 121 et seq.)) and

(b \in C \ Z_{0}^{-}, Z_{0}^{-} = Z^{-} \cup {0} = {0, - 1, - 2, \dots}, s \in C, η \in D)

For

N (0) \neq 0

, the normalized function

_{N} L_{d, b}

(see [18]) is defined by

_{N} L_{d, b} (η) : = η + \sum_{k = 2}^{\infty} \frac{N (k - 1) Γ (b)}{N (0) Γ (d (k - 1) + b)} η^{k}, η \in D .

(4)

If

N (k) = {(k + 1)}^{- r}

,

r \in R

is a non-negative value,

a = 0

and

b = 1

; then, the operator (4) is the integral operator defined by Sălăgean (Sălăgean integral operator of order

r)

(see [45]).

Now, by using the q-gamma function, the class of normalized functions

_{q, N} L_{d, b} (η)

is defined as follows:

_{q, N} L_{d, b} (η) : = η + \sum_{k = 2}^{\infty} Φ_{k} (d, b, N, q) η^{k}, η \in D,

where

Φ_{k} (d, b, N, q) : = \frac{N (k - 1) Γ_{q} (b)}{N (0) Γ_{q} (d (k - 1) + b)},

(5)

with

Re a > 0

,

Re b > 0

and

N (0) \neq 0

.

Considering the quantum operator

d_{q}

, Attiya et al. [18] introduced the q-Raina differential operator

_{N} L_{q}^{n} : Δ \to Δ

by

\begin{matrix} _{N} L_{q}^{0} (a, b) u (η) = u (η) *_{q, N} L_{d, b} (η), \\ _{N} L_{q}^{1} (a, b) u (η) = η d_{q} (_{N} L_{q}^{0} (a, b) u (η)), \\ _{N} L_{q}^{2} (a, b) u (η) =_{N} L_{q}^{1} (a, b) (_{N} L_{q}^{1} (a, b) u (η)), \\ \dots \\ _{N} L_{q}^{k} (a, b) u (η) =_{N} L_{q}^{1} (a, b) (_{N} L_{q}^{k - 1} (a, b) u (η)), u \in Δ, k \in N, k \geq 2 . \end{matrix}

(6)

Employing the above definition and if

u \in Δ

, which is in the form (1), then we have

_{N} L_{q}^{n} (a, b) u (η) = η + \sum_{k = 2}^{\infty} {[k]}_{q}^{n} \frac{N (k - 1) Γ_{q} (b)}{N (0) Γ_{q} (d (k - 1) + b)} a_{k} η^{k}, α \neq 0 .

Analogously to

_{N} L_{q}^{n}

, we add the significant parameter

α (α \neq 0)

for a new operator

L_{q}^{n} (_{N}, a, b, α)

as follows:

\begin{matrix} L_{q}^{n} (_{N}, a, b, α) u (η) & = η + \sum_{k = 2}^{\infty} {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} \frac{N (k - 1) Γ_{q} (b)}{N (0) Γ_{q} (d (k - 1) + b)} a_{k} η^{k}, α \neq 0 \\ = η + \sum_{k = 2}^{\infty} {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} Φ_{k} (d, b, N, q) a_{k} η^{k}, η \in D, \end{matrix}

(7)

where

Φ_{k} (d, b, N, q)

is given by (5)

Remark 2.

(i): Putting $α = 1,$ in (7), we obtain the q-Raina differential operator defined in [18].
(ii): Putting $α = 1$ and $N (k - 1) = 1$ ( $k \geq 1)$ , (7), we obtain the q-differential operator of [22].
(iii): Putting $α = 1, d = 0$ and $N (k - 1) = 1$ ( $k \geq 1)$ in (7), we obtain the Sălăgean q-differential operator defined in [46].
(iv): Putting $α = 1,$ $N (k - 1) = 1$ and $q = 1$ in (7), we obtain the class studied by Bansal and Prajapat [47] (see also [48]).

Definition 2.

Let us define the convex analytic function

Ω_{j, ℑ}

in

D

as follows:

Ω_{j, ℑ} (η) : = \{\begin{matrix} \frac{1 + η}{1 - η}, & if j = 0, \\ ϝ_{1} (j, ℑ), & if j = 1, \\ ϝ_{2} (j, ℑ), & if 0 < j < 1, \\ ϝ_{3} (j, ℑ), & if j > 1, \end{matrix}

where

ℑ \in C \ {0}

, and the following functions are defined by (see [49])

\begin{matrix} ϝ_{1} (j, ℑ) (η) = 1 + \frac{2 ℑ}{π^{2}} {(log (\frac{1 + \sqrt{η}}{1 - \sqrt{η}}))}^{2}, \\ ϝ_{2} (j, ℑ) (η) = 1 + \frac{2 ℑ}{1 - j^{2}} {sinh}^{2} (\frac{2}{π} arccos (j) arctanh (\sqrt{η})), \\ ϝ_{3} (j, ℑ) (η) = 1 + \frac{ℑ}{1 - j^{2}} + \frac{ℑ}{j^{2} - 1} sin (\frac{π}{2 Y (t)} \int_{0}^{ℓ (η) / \sqrt{t}} \frac{d ζ}{\sqrt{1 - ζ^{2}} \sqrt{1 - {(ζ t)}^{2}}}), \end{matrix}

where

ℓ (η) = \frac{η - \sqrt{t}}{1 - \sqrt{t} η}

,

t \in (0, 1)

, taken with

t = cosh (\frac{π Y^{'} (t)}{4 Y (t)})

,

Y (t)

is the well-known Legendre’s complete elliptic integral from the first kind and

Y^{'} (t)

is the complementary integral of Legendre’s function

Y (t)

, which satisfies

{(Y^{'} (t))}^{2} = 1 - {(Y (t))}^{2}

.

Now, we define and introduce the class

S_{q, ℑ}^{n, j} (α, d, b)

of analytic functions as follows:

Definition 3.

The function

u \in Δ

is called to be in the class

S_{q, ℑ}^{n, j} (α, d, b)

if we have the following subordination relation

\frac{α (L_{q}^{n + 1} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} + 1 - α ≺ Ω_{j, ℑ} (η), α \neq 0

where

Ω_{j, ℑ}

in the form (see also [18,49,50])

Ω_{j, ℑ} (η) = 1 + γ_{1} η + γ_{2} η^{2} + \dots, η \in D,

(8)

is given by Definition 2.

Definition 4.

When

q \to 1^{-},

then the function

u \in S_{q, ℑ}^{n, j} (α, d, b)

is said to be in the class

S_{ℑ}^{n, j} (α, d, b)

.

Lemma 1

([51]). Let

G (η) = \sum_{k = 0}^{\infty} g_{k} η^{k}

be a univalent convex function in

D

satisfying the inequality

H (η) = \sum_{k = 0}^{\infty} h_{k} η^{k} ≺ G (η) .

Then,

| h_{k} | \leq | g_{1} |

for all

k \geq 1

.

Lemma 2

([52]). Let

P (η) = 1 + \sum_{k = 1}^{\infty} p_{k} η^{k}

be analytic in

D

that satisfies

Re P (η) > 0

(η \in D)

. Then,

|p_{2} - ℵ p_{1}^{2}| \leq 2 max {1; | 2 ℵ - 1 |}, ℵ \in C .

2. Estimation Coefficient for the Class $S_{q, ℑ}^{n, j} (α, d, b)$

The following theorem is related to functions in the class

S_{ℑ}^{n, j} (α, d, b)

Theorem 1.

If u is in the class

S_{ℑ}^{n, j} (α, d, b)

, then

L_{q}^{n} (_{N}, d, b, α) u (η) ≺ η exp (\int_{0}^{η} \frac{Ω_{j, ℑ} (ω (χ)) - 1}{χ} d χ),

where ω is a Schwarz function where

ω (0) = 0

and also,

ω (η) | < 1

,

η \in D

. Furthermore, for

| η | : = ϱ < 1

, we obtain

exp (\int_{0}^{1} \frac{Ω_{j, ℑ} (- ϱ) - 1}{ϱ} d ϱ) \leq |\frac{L_{q}^{n} (_{N}, d, b, α) u (η)}{η}| \leq exp (\int_{0}^{1} \frac{Ω_{j, ℑ} (ϱ) - 1}{ϱ} d ϱ) .

Proof.

Since

u \in S_{ℑ}^{n, j} (α, d, b)

, then

\frac{{(L_{q}^{n} (_{N}, d, b, α) u (η))}^{'}}{L_{q}^{n} (_{N}, d, b, α) u (η)} - \frac{1}{η} = \frac{Ω_{j, ℑ} (ω (η)) - 1}{η}, η \in D .

(9)

Integrating both sides of (9), it follows that

L_{q}^{n} (_{N}, d, b, α) u (η) ≺ η exp (\int_{0}^{η} \frac{Ω_{j, ℑ} (χ) - 1}{χ} d χ),

which is equivalent to

\frac{L_{q}^{n} (_{N}, d, b, α) u (η)}{η} ≺ exp (\int_{0}^{η} \frac{Ω_{j, ℑ} (χ) - 1}{χ} d χ) .

Since

Ω_{j, ℑ} (- ϱ | η |) \leq Re (Ω_{j, ℑ} (ω (η ϱ))) \leq Ω_{j, ℑ} (ϱ | η |),

this yields

\int_{0}^{1} \frac{Ω_{j, ℑ} (- ϱ | η |) - 1}{ϱ} d ϱ \leq \int_{0}^{1} \frac{Re (Ω_{j, ℑ} (ω (η ϱ))) - 1}{ϱ} d ϱ \leq \int_{0}^{1} \frac{Ω_{j, ℑ} (ϱ | η |) - 1}{ϱ} d ϱ .

Therefore, we obtain

\int_{0}^{1} \frac{Ω_{j, ℑ} (- ϱ | η |) - 1}{ϱ} d ϱ \leq log |\frac{L_{q}^{n} (_{N}, d, b, α) u (η)}{η}| \leq \int_{0}^{1} \frac{Ω_{j, ℑ} (ϱ | η |) - 1}{ϱ} d ϱ,

then

exp (\int_{0}^{1} \frac{Ω_{j, ℑ} (- ϱ) - 1}{ϱ} d ϱ) \leq |\frac{L_{q}^{n} (_{N}, d, b, α) u (η)}{η}| \leq exp (\int_{0}^{1} \frac{Ω_{j, ℑ} (ϱ) - 1}{ϱ} d ϱ) .

□

Remark 3.

Theorem 1 represents a generalization of results of some authors, e.g.,

1.: Putting $α = 1,$ in Theorem 1, we have the result due to Attiya et al. ([18], Theorem 6).
2.: Putting $α = 1$ and $N (k) = 1$ for all $k \geq 1,$ in Theorem 1, we have the result due to Noor and Razzaque ([22], Theorem 6).
3.: Putting $α = 1$ , $N (k) = 1$ $(k \geq 1),$ $d = 0$ and $b = 1$ , then in Theorem 1, we have the result due to Hussain et al. ([53], Theorem 3.1).

Theorem 2.

If u belongs to the class

S_{q, ℑ}^{n, j} (α, d, b)

, then

\begin{matrix} | a_{2} | & \leq \frac{| γ_{1} |}{q {|\frac{q}{α} + 1|}^{n} Φ_{2} (d, b, N, q)}, a n d \\ | a_{k} | & \leq \frac{| γ_{1} |}{q {[k - 1]}_{q} {|1 + \frac{q {[k - 1]}_{q}}{α}|}^{n} Φ_{k} (d, b, N, q)} \prod_{j = 1}^{k - 2} (1 + \frac{| γ_{1} |}{q {[j]}_{q} {|1 + \frac{q {[j]}_{q}}{α}|}^{n}}), k \geq 3 \end{matrix}

where

α \neq 0

and

γ_{1}

is defined by (8).

Proof.

Letting

P (η) = \frac{α (L_{q}^{n + 1} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} + 1 - α

therefore,

P (η) = \frac{η d_{q} (L_{q}^{n} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} (η \in D),

letting

P (η) = 1 + \sum_{k = 1}^{\infty} p_{k} η^{k}

, which gives

η d_{q} (L_{q}^{n} (_{N}, d, b, α) u (η)) = (L_{q}^{n} (_{N}, d, b, α) u (η)) P (η), η \in D,

therefore, we have

\begin{matrix} η + \sum_{k = 2}^{\infty} {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} {[k]}_{q} Φ_{k} (d, b, N, q) a_{k} η^{k} \\ = (η + \sum_{k = 2}^{\infty} {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} Φ_{k} (d, b, N, q) a_{k} η^{k}) (1 + \sum_{k = 1}^{\infty} p_{k} η^{k}) \\ = \sum_{k = 0}^{\infty} p_{k} η^{k + 1} + \sum_{k = 0}^{\infty} p_{k} η^{k} \cdot \sum_{k = 2}^{\infty} {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} Φ_{k} (d, b, N, q) a_{k} η^{k} . (p_{0} = 1) \\ = η + \sum_{k = 2}^{\infty} (p_{k - 1} + \sum_{j = 1}^{k - 1} {(\frac{{[j + 1]}_{q} + (α - 1)}{α})}^{n} Φ_{j + 1} (d, b, N, q) a_{j + 1} p_{k - j - 1}) η^{k} . \end{matrix}

By matching the coefficients of

η^{k}

of the equality mentioned above, we obtain

\begin{matrix} {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} {[k]}_{q} Φ_{k} (d, b, N, q) a_{k} & = p_{k - 1} + {(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} Φ_{k} (d, b, N, q) a_{k} \\ + \sum_{j = 1}^{k - 2} {(\frac{{[j + 1]}_{q} + (α - 1)}{α})}^{n} Φ_{j + 1} (d, b, N, q) a_{j + 1} p_{k - j - 1}, \end{matrix}

which gives

{(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} ({[k]}_{q} - 1) Φ_{k} (d, b, N, q) a_{k} = p_{k - 1} + \sum_{j = 1}^{k - 2} {(\frac{{[j + 1]}_{q} + (α - 1)}{α})}^{n} Φ_{j + 1} (d, b, N, q) a_{j + 1} p_{k - j - 1} .

Accordingly, we obtain

a_{k} = \frac{1}{{(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} ({[k]}_{q} - 1) Φ_{k} (d, b, N, q)} (\sum_{j = 1}^{k - 1} {(\frac{{[j]}_{q} + (α - 1)}{α})}^{n} Φ_{j} (d, b, N, q) a_{j} p_{k - j}),

for some calculation implies that

a_{k} = \frac{1}{{(\frac{{[k]}_{q} + (α - 1)}{α})}^{n} ({[k]}_{q} - 1) Φ_{k} (d, b, N, q)} \sum_{j = 1}^{k - 1} {(\frac{{[j]}_{q} + (α - 1)}{α})}^{n} \frac{N (j - 1) Γ_{q} (b)}{N (0) Γ_{q} (d (j - 1) + b)} a_{j} p_{k - j} .

In view of Lemma 1, since

| p_{k} | \leq | γ_{1} |

, we obtain

| a_{k} | \leq \frac{| γ_{1} |}{{|\frac{{[k]}_{q} + (α - 1)}{α}|}^{n} ({[k]}_{q} - 1) Φ_{k} (d, b, N, q)} \sum_{j = 1}^{k - 1} {|\frac{{[j]}_{q} + (α - 1)}{α}|}^{n} \frac{N (j - 1) Γ_{q} (b)}{N (0) Γ_{q} (d (j - 1) + b)} | a_{j} | .

For

k = 2

, we have

\begin{matrix} | a_{2} | \leq \frac{| γ_{1} |}{q {|1 + \frac{q}{α}|}^{n} Φ_{2} (d, b, N, q)} \sum_{j = 1}^{1} {|\frac{{[j]}_{q} + (α - 1)}{α}|}^{n} \frac{N (j - 1) Γ_{q} (b)}{N (0) Γ_{q} (d (j - 1) + b)} | a_{j} | \\ = \frac{| γ_{1} |}{q {|1 + \frac{q}{α}|}^{n} Φ_{2} (d, b, N, q)}, \end{matrix}

while if

k = 3

, and using the above inequality, then

| a_{3} | \leq \frac{| γ_{1} |}{q {[2]}_{q} {|1 + \frac{q {[2]}_{q}}{α}|}^{n} Φ_{3} (d, b, N, q)} (1 + \frac{| γ_{1} |}{q {|1 + \frac{q}{α}|}^{n}}) .

For

k \geq 3

, the following inequality is valid by mathematical induction

| a_{k} | \leq \frac{| γ_{1} |}{q {[k - 1]}_{q} {|1 + \frac{q {[k - 1]}_{q}}{α}|}^{n} Φ_{k} (d, b, N, q)} \prod_{j = 1}^{k - 2} (1 + \frac{| γ_{1} |}{q {[j]}_{q} {|1 + \frac{q {[j]}_{q}}{α}|}^{n}}), k \geq 3 .

which completes our proof. □

For special cases of Theorem 2, we obtain the following corollaries

Corollary 1

([18], Theorem 2). If u

\in S_{q, ℑ}^{n, j} (1, d, b)

, then we have

\begin{matrix} | a_{2} | & \leq \frac{| γ_{1} |}{{[2]}_{q}^{n} ({[2]}_{q} - 1) Φ_{2} (d, b, N, q)}, a n d \\ | a_{k} | & \leq \frac{| γ_{1} |}{{[k]}_{q}^{n} ({[k]}_{q} - 1) Φ_{k} (d, b, N, q)} \prod_{j = 1}^{k - 2} (1 + \frac{| ρ_{1} |}{{[j + 1]}_{q} - 1}), k \geq 3 \end{matrix}

with

γ_{1}

given by (8).

Corollary 2

([22], Theorem 8). If u

\in S_{q, ℑ}^{n, j} (1, d, b)

and

N (k) = 1

for all

k \geq 1

, then

\begin{matrix} | a_{2} | \leq \frac{| γ_{1} |}{{[2]}_{q}^{n} Φ_{2} (d, b, 1, q) ({[2]}_{q} - 1)}, a n d \\ | a_{k} | \leq \frac{| γ_{1} |}{{[k]}_{q}^{n} Φ_{k} (d, b, 1, q) ({[k]}_{q} - 1)} \prod_{j = 1}^{k - 2} (1 + \frac{| γ_{1} |}{{[j + 1]}_{q} - 1}), k \geq 3, \end{matrix}

with

γ_{1}

given by (8).

Corollary 3

([53], Theorem 3.2). If u

\in S_{q, ℑ}^{n, j} (1, 0, 1)

and

N (k) = 1

for all

k \geq 1

, then

\begin{matrix} | a_{2} | \leq \frac{| γ_{1} |}{{[2]}_{q}^{n} Φ_{2} (0, 1, 1, q) ({[2]}_{q} - 1)}, a n d \\ | a_{k} | \leq \frac{| γ_{1} |}{{[k]}_{q}^{n} Φ_{k} (0, 1, 1, q) ({[k]}_{q} - 1)} \prod_{j = 1}^{k - 2} (1 + \frac{| γ_{1} |}{{[j + 1]}_{q} - 1}), k \geq 3, \end{matrix}

where

γ_{1}

is given by (8).

3. Fekete–Szegő Problem Associated with Class $S_{q, ℑ}^{n, j} (α, d, b)$

In the following theorem, we will give estimation for the Fekete–Szegő problem for the class

S_{q, ℑ}^{n, j} (α, d, b)

.

Theorem 3.

If

u \in S_{q, ℑ}^{n, j} (α, d, b)

, then

| a_{3} - ψ a_{2}^{2} | \leq \frac{| γ_{1} |}{2 T Φ_{3} (d, b, N, q)} max {1; | 2 Ψ - 1 |},

where

ψ \in C

, and

Ψ : = Ψ (d, b, N, q) = \frac{2 T Φ_{3} (d, b, N, q)}{γ_{1}} (\frac{U}{T Φ_{3} (d, b, N, q)} - \frac{ψ γ_{1}^{2}}{q^{2} {(1 + \frac{q}{α})}^{2 n} Φ_{2}^{2} (d, b, N, q)}),

(10)

with

T = (1 - {[3]}_{q}) {(\frac{{[3]}_{q} - (1 - α)}{α})}^{n}

and

U = \frac{1}{4} (γ_{1} (\frac{q - γ_{1}}{4 q}) - γ_{2}^{2}),

where

γ_{1}

and

γ_{2}

defined by (8).

Proof.

From the condition

u \in S_{q, ℑ}^{n, j} (α, d, b)

, we have

\frac{α (L_{q}^{n + 1} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} + 1 - α = Ω_{j, ℑ} (ω (η)),

where

ω

is a Schwarz function (

ω (0) = 0,

ω (η) | < 1

).

Let

p \in P

be defined as follows

p (η) = \frac{1 + ω (η)}{1 - ω (η)} = 1 + p_{1} η + p_{2} η^{2} + \dots, η \in D,

which implies

ω (η) = \frac{p_{1}}{2} η + \frac{1}{2} (p_{2} - \frac{p_{1}^{2}}{2}) η^{2} + \dots, η \in D

and

Ω_{j, ℑ} (ω (η)) = 1 + \frac{γ_{1} p_{1}}{2} η + (\frac{γ_{2} p_{1}^{2}}{4} + \frac{1}{2} (p_{2} - \frac{p_{1}^{2}}{2}) γ_{1}) η^{2} + \dots, η \in D .

Therefore, we obtain

\begin{matrix} \frac{α (L_{q}^{n + 1} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} + 1 - α = 1 + (q a_{2} {(1 + \frac{q}{α})}^{n} Φ_{2} (d, b, N, q)) η \\ + (\begin{matrix} ({[3]}_{q} - 1) {(\frac{{[3]}_{q} - 1}{α} + 1)}^{n} Φ_{3} (d, b, N, q) a_{3} - (q {(1 + \frac{q}{α})}^{2 n} Φ_{2}^{2} (d, b, N, q)) a_{2}^{2} \end{matrix}) η^{2} + \dots, η \in D, \end{matrix}

thus, the following coefficients can be determined as follows:

\begin{matrix} a_{2} = \frac{γ_{1} p_{1}}{q [{(1 + \frac{q}{α})}^{n} Φ_{2} (d, b, N, q)}, \\ a_{3} = \frac{1}{T Φ_{3} (d, b, N, q) ({[3]}_{q} - 1)} (- \frac{γ_{1} p_{2}}{2} + p_{1}^{2} (- \frac{γ_{2}^{2}}{4} + \frac{γ_{1}}{4} - \frac{γ_{1}^{2}}{q})) \\ a_{3} - ψ a_{2}^{2} = \frac{1}{T Φ_{3} (d, b, N, q)} (- \frac{γ_{1} p_{2}}{2} + U p_{1}^{2}) \\ - ψ {(\frac{γ_{1} p_{1}}{q [(1 + \frac{q}{α}) Φ_{2} (d, b, N, q)})}^{2} . \end{matrix}

A simple computation yields

a_{3} - ψ a_{2}^{2} = \frac{- γ_{1}}{2 T Φ_{3} (d, b, N, q)} (p_{2} - Ψ p_{1}^{2}),

where

ψ \in C

and

Ψ

is defined by (10). Therefore, by using Lemma 2, we obtain the desired result. □

Theorem 3 generalizes some of the previous results, e.g.,

Corollary 4

([18], Theorem 3). If

u \in S_{q, ℑ}^{n, j} (1, d, b)

, then

| a_{3} - ψ a_{2}^{2} | \leq \frac{| ρ_{1} |}{2 {[3]}_{q}^{n} Φ_{3} (a, b, M, q) ({[3]}_{q} - 1)} max {1; | 2 Ψ - 1 |},

where

ψ \in C

, and

Ψ : = Ψ (a, b, M, q) = \frac{1}{2} (1 - \frac{ρ_{2}}{ρ_{1}} - ρ_{1} (\frac{1}{{[2]}_{q} - 1} - ψ \frac{{[3]}_{q}^{n} ({[3]}_{q} - 1)}{2 Φ_{2} (a, b, M, q) {({[2]}_{q}^{n} ({[2]}_{q} - 1))}^{2}})),

(11)

with

ρ_{1}

and

ρ_{2}

defined by (8).

Corollary 5

([22], Theorem 10). If

u \in S_{q, ℑ}^{n, j} (1, d, b)

with

N (k) = 1

for all

k \geq 1

, then

| a_{3} - ψ a_{2}^{2} | \leq \frac{| γ_{1} |}{2 {[3]}_{q}^{n} Φ_{3} (d, b, 1, q) ({[3]}_{q} - 1)} max {1; | 2 \hat{Ψ} - 1 |},

where

ψ \in C

, and

\hat{Ψ} : = Ψ (d, b, 1, q) = \frac{1}{2} (1 - \frac{γ_{2}}{γ_{1}} - γ_{1} (\frac{1}{{[2]}_{q} - 1} - ψ \frac{{[3]}_{q}^{n} ({[3]}_{q} - 1)}{2 Φ_{2} (d, b, 1, q) {({[2]}_{q}^{n} ({[2]}_{q} - 1))}^{2}})),

with

γ_{1}

and

γ_{2}

given by (8).

Corollary 6

([53], Theorem 3.3). If

u \in S_{q, ℑ}^{n, j} (1, 0, 1)

with

N (k) = 1

for all

k \geq 1

, then

| a_{3} - ψ a_{2}^{2} | \leq \frac{| γ_{1} |}{2 {[3]}_{q}^{n} Φ_{3} (0, 1, 1, q) ({[3]}_{q} - 1)} max {1; | 2 \tilde{Ψ} - 1 |},

where

ψ \in C

, and

\tilde{Ψ} : = Ψ (0, 1, 1, q) = \frac{1}{2} (1 - \frac{γ_{2}}{γ_{1}} - γ_{1} (\frac{1}{{[2]}_{q} - 1} - ψ \frac{{[3]}_{q}^{n} ({[3]}_{q} - 1)}{2 Φ_{2} (0, 1, 1, q) {({[2]}_{q}^{n} ({[2]}_{q} - 1))}^{2}})),

with

γ_{1}

and

γ_{2}

defined by (8).

The following result is related to the sufficient condition of the functions belonging to the class

S_{q, ℑ}^{n, j} (α, d, b)

.

Theorem 4.

Let

u \in Δ

be of the form (1). If

\sum_{k = 2}^{\infty} (({[k]}_{q} - 1) (j + 1) + | ℑ |) | Φ_{k} (d, b, N, q) | {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} | a_{k} | \leq | ℑ |,

then

u \in S_{q, ℑ}^{n, j} (α, d, b)

.

Proof.

Obviously, we have

\begin{matrix} |\frac{η d_{q} (_{m} L_{q}^{n} (_{N}, d, b, α) u (η))}{_{m} L_{q}^{n} (d, b) u (η)} - 1| \\ = |\frac{η d_{q} (_{m} L_{q}^{n} (d, b) u (η)) - L_{q}^{n} (_{N}, d, b, α) u (η)}{_{m} L_{q}^{n} (d, b) u (η)}| \\ = |\frac{\sum_{k = 2}^{\infty} ({[k]}_{q} - 1) {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q) a_{k} η^{k}}{η + \sum_{k = 2}^{\infty} {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q) a_{k} η^{k}}| \\ \leq \frac{\sum_{k = 2}^{\infty} |({[k]}_{q} - 1) {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q)| | a_{k} |}{1 - \sum_{k = 2}^{\infty} | {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q) | | a_{k} |}, η \in D, \end{matrix}

and from the assumption of the theorem

1 - \sum_{k = 2}^{\infty} |{(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q)| | a_{k} | > 0 .

Since

\begin{matrix} |\frac{j}{ℑ} (\frac{η d_{q} (L_{q}^{n} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} - 1)| - Re (\frac{1}{ℑ} (\frac{η d_{q} (L_{q}^{n} (_{N}, d, b, α) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} - 1)) \\ \leq \frac{j}{| ℑ |} |(\frac{η d_{q} (_{m} L_{q}^{n} (d, b) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} - 1)| + |\frac{1}{ℑ}| |\frac{η d_{q} (_{m} L_{q}^{n} (d, b) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} - 1| \\ = \frac{j + 1}{| ℑ |} |(\frac{η d_{q} (_{m} L_{q}^{n} (d, b) u (η))}{L_{q}^{n} (_{N}, d, b, α) u (η)} - 1)| = \frac{j + 1}{| ℑ |} |\frac{η d_{q} (L_{q}^{n} (_{N}, d, b, α) u (η)) - L_{q}^{n} (_{N}, d, b, α) u (η)}{L_{q}^{n} (_{N}, d, b, α) u (η)}| \\ \leq \frac{j + 1}{| ℑ |} (\frac{\sum_{k = 2}^{\infty} | ({[k]}_{q} - 1) {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q) | | a_{k} |}{1 - \sum_{k = 2}^{\infty} | {(\frac{{[k]}_{q} - 1}{α} + 1)}^{n} Φ_{k} (d, b, N, q) | | a_{k} |}) \leq 1, η \in D, \end{matrix}

we obtain

u \in S_{q, ℑ}^{n, j} (α, d, b)

. □

We can see Theorem 4 generalizes other previously obtained results, e.g.,

Corollary 7

([18], Theorem 4). Let

u \in Λ

be in the form (1). If

\sum_{k = 2}^{\infty} (({[k]}_{q} - 1) (j + 1) + | ℘ |) | Φ_{k} {(a, b, M, q) | [n]}_{q}^{k} | a_{k} | \leq | ℘ |,

then

h \in S_{q, ℑ}^{n, j} (1, d, b)

.

Corollary 8

([22], Theorem 12). Let

u \in Δ

be of the form (1). If

\sum_{k = 2}^{\infty} (({[k]}_{q} - 1) (j + 1) + | ℑ |) | Φ_{k} {(d, b, 1, q) | [k]}_{q}^{n} | a_{k} | \leq | ℑ |,

then

\frac{η d_{q} (L_{q}^{n} (d, b) u (η))}{L_{q}^{n} (d, b) u (η)} ≺ Ω_{j, ℑ} (η) .

That is,

u \in S_{q, ℑ}^{n, j} (α, d, b)

, when

N (k) = 1

for all

k \geq 1

.

Corollary 9

([53], Theorem 3.4). Let

u \in Δ

be of the form (1). If

\sum_{k = 2}^{\infty} (({[k]}_{q} - 1) (j + 1) + | ℑ |) | Φ_{k} {(0, 1, 1, q) | [k]}_{q}^{n} | a_{k} | \leq | ℑ |,

then

\frac{η d_{q} (L_{q}^{n} (0, 1) u (η))}{L_{q}^{n} (0, 1) u (η)} ≺ Ω_{j, ℑ} (η) .

That is,

u \in S_{q, ℑ}^{n, j} (0, 1)

, when

N (k) = 1

for all

k \geq 1

.

4. Conclusions

By using a Jackson differential operator and generalized Mittag–Leffler function, we introduced the class

S_{q, ℑ}^{n, j} (α, d, b)

of analytic functions in the unit disk. The coefficient bounds and the Fekete–Szegő problem have been obtained by using differential subordination in the geometric function theorem. A sufficient condition for the coefficients of the functions belonging to

S_{q, ℑ}^{n, j} (α, d, b)

has been considered. Furthermore, we highlighted some special results of cases for the class

S_{q, ℑ}^{n, j} (α, d, b)

, which have been studied before. In the future work, using other classes of analytic functions which are associated with operators in Geometric Function Theory (GFT), the authors may study various new geometric properties and their applications in GFT.

Author Contributions

The authors contributed equally to the writing of this paper. All authors have read and agreed to the published version of the manuscript.

Funding

This research has been funded by the Deputy for Research & Innovation, Ministry of Education through the Initiative of Institutional Funding at University of Ha’il-Saudi Arabia through project number IFP-22069.

Data Availability Statement

No data were used to support this study.

Conflicts of Interest

The authors declare no conflict of interest.

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Attiya, A.A.; Yassen, M.F.; Albaid, A. Jackson Differential Operator Associated with Generalized Mittag–Leffler Function. Fractal Fract. 2023, 7, 362. https://doi.org/10.3390/fractalfract7050362

AMA Style

Attiya AA, Yassen MF, Albaid A. Jackson Differential Operator Associated with Generalized Mittag–Leffler Function. Fractal and Fractional. 2023; 7(5):362. https://doi.org/10.3390/fractalfract7050362

Chicago/Turabian Style

Attiya, Adel A., Mansour F. Yassen, and Abdelhamid Albaid. 2023. "Jackson Differential Operator Associated with Generalized Mittag–Leffler Function" Fractal and Fractional 7, no. 5: 362. https://doi.org/10.3390/fractalfract7050362

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Jackson Differential Operator Associated with Generalized Mittag–Leffler Function

Abstract

1. Introduction

2. Estimation Coefficient for the Class $S_{q, ℑ}^{n, j} (α, d, b)$

3. Fekete–Szegő Problem Associated with Class $S_{q, ℑ}^{n, j} (α, d, b)$

4. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

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Jackson Differential Operator Associated with Generalized Mittag–Leffler Function

Abstract

1. Introduction

2. Estimation Coefficient for the Class S q , ℑ n , j ( α , d , b )

3. Fekete–Szegő Problem Associated with Class S q , ℑ n , j ( α , d , b )

4. Conclusions

Author Contributions

Funding

Data Availability Statement

Conflicts of Interest

References

Share and Cite

Article Metrics

Article Access Statistics

Further Information

Guidelines

MDPI Initiatives

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2. Estimation Coefficient for the Class $S_{q, ℑ}^{n, j} (α, d, b)$

3. Fekete–Szegő Problem Associated with Class $S_{q, ℑ}^{n, j} (α, d, b)$