Applications of Higher-Order q-Derivative to Meromorphic q-Starlike Function Related to Janowski Function

Liu, Likai; Srivastava, Rekha; Liu, Jin-Lin

doi:10.3390/axioms11100509

Open AccessArticle

Applications of Higher-Order q-Derivative to Meromorphic q-Starlike Function Related to Janowski Function

by

Likai Liu

¹,

Rekha Srivastava

²

and

Jin-Lin Liu

^3,*

¹

Information Technology Department, Nanjing Vocational College of Information Technology, Nanjing 210023, China

²

Department of Mathematics and Statistics, University of Victoria, Victoria, BC V8W 3R4, Canada

³

Department of Information Science, Yangzhou University, Yangzhou 225002, China

^*

Author to whom correspondence should be addressed.

Axioms 2022, 11(10), 509; https://doi.org/10.3390/axioms11100509

Submission received: 11 August 2022 / Revised: 20 September 2022 / Accepted: 25 September 2022 / Published: 27 September 2022

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

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Abstract

:

By making use of a higher-order q-derivative operator, certain families of meromorphic q-starlike functions and meromorphic q-convex functions are introduced and studied. Several sufficient conditions and coefficient inequalities for functions in these subclasses are derived. The results presented in this article extend and generalize a number of previous results.

Keywords:

q-derivative; analytic functions; differential subordination; meromorphic functions; meromorphic q-starlike functions; meromorphic q-convex functions

MSC:

30C45; 05A30

1. Introduction

Recently, q-analysis has fascinated scholars due to various applications in many areas of physics and mathematics. The applications of q-analysis were first considered by Jackson [1,2]. In recent years, some scholars have written a number of papers [3,4,5,6,7,8,9,10,11,12,13,14,15] associated with q-starlike functions and the Janowski functions [16]. In particular, Srivastava [17,18] pointed out some applications and mathematical explanations of q-derivatives in GFT. In this paper, we consider several families of meromorphically multivalent q-starlike functions by making use of the Janowski function and the higher-order q-derivative. Certain sufficient conditions and coefficient inequalities for functions in these subclasses are derived. Moreover, several previous results are generalized.

Let

Σ (p) (p \in N)

denote the family of p-valent analytic functions in

U^{*} = {z : 0 < | z | < 1}

which have the following form:

f (z) = z^{- p} + \sum_{k = 1}^{\infty} a_{k - p} z^{k - p} .

(1)

Furthermore, we let

Σ (1) = Σ

.

If

f \in Σ (p)

satisfies the condition

Re (- \frac{z f^{'} (z)}{f (z)}) > 0,

(2)

then f is called a meromorphic p-valent starlike function. We note the family by

M Σ^{*} (p)

and write

M Σ^{*} (1) = M Σ^{*}

. The class

M Σ^{*}

was studied by Pommerenke [19].

If

f \in Σ (p)

satisfies the condition

Re (- \frac{{(z f^{'} (z))}^{'}}{f^{'} (z)}) > 0,

(3)

then f is called a meromorphic p-valent convex function. We note this family by

M C (p)

and write

M C (1) = M C

.

If a function

ψ

is analytic in

U = U^{*} \cup {0}

and satisfies

ψ (z) = 1 + \sum_{k = 1}^{\infty} ψ_{k} z^{k}

(4)

and

Re (ψ (z)) > 0,

then

ψ

is said to be in the family P.

Let

φ

be analytic in U and

φ (0) = 1

. If

φ

satisfies

φ (z) ≺ \frac{A z + 1}{B z + 1} (- 1 ≦ B < A ≦ 1),

then

φ

is said to be in

P [A, B]

.

In [16], Janowski studied the family

P [A, B]

and obtained that

φ

is in

P [A, B]

if

φ (z) = \frac{(1 - A) + (1 + A) ψ (z)}{(1 - B) + (1 + B) ψ (z)} (ψ \in P; - 1 ≦ B < A ≦ 1) .

Let f and g be analytic in U. If there exists w analytic in U with

w (0) = 0

and

| w (z) | < 1

, so that

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

then we say that f is subordinate to g, written by

f ≺ g

. Further, if the function g is analytic and univalent in U, then

f ≺ g (z \in U) ⟺ f (U) \subset g (U) and f (0) = g (0) .

Definition 1.

Let

f \in Σ

. Then f is called to be in

M Σ^{*} [A, B]

if

- \frac{z f^{'} (z)}{f (z)} = \frac{(1 - A) + (1 + A) ψ (z)}{(1 - B) + (1 + B) ψ (z)} (- 1 ≦ B < A ≦ 1; ψ \in P) .

(5)

In [20], Karunakaran studied the family

M Σ^{*} [A, B]

.

Let

0 < q < 1

and define

{[τ]}_{q}

as the following:

{[τ]}_{q} = \{\begin{matrix} \frac{q^{τ} - 1}{q - 1} & (τ \in C) \\ \sum_{k = 0}^{n - 1} q^{k} = 1 + q + q^{2} + \dots + q^{n - 1} & (τ = n \in N) . \end{matrix}

Let

0 < q < 1

. The q-factorial

{[m]}_{q}!

is defined by

{[m]}_{q}! = \{\begin{matrix} 1 & (m = 0) \\ Π_{k = 1}^{m} {[k]}_{q} & (m \in N) . \end{matrix}

Let

γ \in N

. We define q-Pochhammer symbol

{[γ]}_{q, n}

by (see [21])

{[γ]}_{q, n} = \{\begin{matrix} 1 & (n = 0) \\ Π_{k = γ}^{γ + n - 1} {[k]}_{q} & (n \in N) . \end{matrix}

Specifically, we write

{[0]}_{q, n} = 0

.

Next, we define the q-derivative

D_{q}

(0 < q < 1)

for

f \in Σ (p)

by

\begin{matrix} (D_{q} f) (z) & = \frac{f (z q) - f (z)}{z (q - 1)} \\ = - \sum_{k = 1}^{p} (\frac{{[k]}_{q, 1}}{q^{k}}) a_{- k} z^{- 1 - k} + \sum_{k = 1}^{\infty} {[k]}_{q} a_{k} z^{- 1 + k}, \end{matrix}

(6)

where

a_{- p} = 1

.

From (6), we can see that

lim_{q \to 1} (D_{q} f) (z) = lim_{q \to 1} \frac{f (z q) - f (z)}{z (q - 1)} = f^{'} (z) .

Further, one can find that

(D_{q}^{(2)} f) (z) = \sum_{k = 1}^{p} (\frac{{[k]}_{q, 2}}{q^{2 k + 1}}) a_{- k} z^{- k - 2} + \sum_{k = 2}^{\infty} {[k - 1]}_{q, 2} a_{k} z^{k - 2},

(7)

(D_{q}^{(3)} f) (z) = - \sum_{k = 1}^{p} (\frac{{[k]}_{q, 3}}{q^{3 k + 3}}) a_{- k} z^{- k - 3} + \sum_{k = 3}^{\infty} {[k - 2]}_{q, 3} a_{k} z^{k - 3},

(8)

\dots \dots \dots

(D_{q}^{(p)} f) (z) = {(- 1)}^{p} \sum_{k = 1}^{p} (\frac{{[k]}_{q, p}}{q^{p [k + \frac{1}{2} (p - 1)]}}) a_{- k} z^{- k - p} + \sum_{k = p}^{\infty} {[k - p + 1]}_{q, p} a_{k} z^{k - p},

(9)

where

a_{- p} = 1

and

D_{q}^{(p)}

is called pth order q-derivatives.

Definition 2.

Let

f \in Σ

. If f satisfies

|\frac{q z D_{q} f (z)}{f (z)} + \frac{1}{1 - q}| < \frac{1}{1 - q},

(10)

then f is called to be in the meromorphic q-starlike function family

M Σ_{q}^{*}

.

It is easily seen that, when

q \to 1^{-}

, the disk given by (10) becomes

Re (- \frac{z f^{'} (z)}{f (z)}) > 0 .

Thus, the class

M Σ_{q}^{*}

reduces to the meromorphic starlike function family

M Σ^{*}

(see [19]).

Furthermore, we can rewrite (10) as the following:

- \frac{q z D_{q} f (z)}{f (z)} ≺ \hat{h} (z) where \hat{h} (z) = \frac{z + 1}{1 - q z} .

Further, the meromorphic q-convex function family

M C_{q}

could be derived by

f (z) \in M C_{q} \Leftrightarrow - q z D_{q} f (z) \in M Σ_{q}^{*} .

Definition 3.

If a function

f \in Σ (p)

satisfies

- \frac{q^{2 p - 1} z (D_{q}^{(p)} f) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} f) (z)} ≺ \frac{(A + 1) \hat{h} (z) + (1 - A)}{(B + 1) \hat{h} (z) + (1 - B)} (\hat{h} (z) = \frac{z + 1}{1 - q z} - 1; ≦ B < A ≦ 1),

or, equivalently,

- \frac{q^{2 p - 1} z (D_{q}^{(p)} f) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} f) (z)} ≺ s (z),

(11)

where

s (z) = \frac{z (1 + A) - z q (1 - A) + 2}{z (1 + B) - z q (1 - B) + 2} (0 < q < 1; - 1 ≦ B < A ≦ 1),

(12)

then f is in the family

M Σ_{q}^{*} [p, A, B]

.

Remark 1.

We write the following special cases:

(i): $M Σ_{q}^{*} [1, A, B] = M Σ_{q}^{*} [A, B]$ , when $p = 1$ .
(ii): ${lim}_{q \to 1^{-}} M Σ_{q}^{*} [1, A, B] = M Σ^{*} [A, B]$ , when $p = 1$ .
(iii): $M Σ_{q}^{*} [p, A, B] = M Σ_{q}^{*} [α]$ , when $p = 1$ , $A = 1 - 2 α$ $(0 ≦ α < 1)$ and $B = - 1$ . In [19], Pommerenke considered the family $M Σ_{q}^{*} [α]$ .

Now we define the meromorphic q-convex function family

M C_{q} [p, A, B]

by

f \in M C_{q} [p, A, B] ⟺ \frac{{(- 1)}^{p} q^{\frac{1}{2} p (3 p - 1)}}{{[p]}_{q, p}} z^{p} D_{q}^{(p)} f \in M Σ_{q}^{*} [p, A, B] .

In particular, we write

M C_{q} [p, A, B] = M C_{q} [A, B]

when

p = 1

.

Lemma 1

([22]). Let

ψ (z) = 1 + ψ_{1} z + ψ_{2} z^{2} + \dots

belong to the family P. Then

| ψ_{2} - ν ψ_{1}^{2} | ≦ \{\begin{matrix} 4 ν - 2 & (ν > 1) \\ 2 & (0 ≦ ν ≦ 1) \\ - 4 ν + 2 & (ν < 0) . \end{matrix}

(13)

Lemma 2

([23]). Let

h (z) = 1 + \sum_{k = 1}^{\infty} h_{k} z^{k}

be analytic in U. Furthermore, let

H (z) = 1 + \sum_{k = 1}^{\infty} C_{k} z^{k}

be univalent convex in U. If

h (z) ≺ H (z)

, then

| h_{k} | ≦ | C_{1} | (k ≧ 1) .

2. Main Results

Theorem 1.

If

g (z) = z^{- p} + \sum_{k = 1}^{\infty} a_{- p + k} z^{- p + k} \in M Σ_{q}^{*} [p, A, B] (p ≧ 2),

then

| a_{2 - p} - μ a_{1 - p}^{2} | ≦ \{\begin{matrix} (\frac{A - B}{2}) (\frac{{[2 p - 3]}_{q, 3}}{q^{2 p - 2} {[p - 2]}_{q, 2}}) Λ (q) & (μ > σ_{1}) \\ (\frac{A - B}{2}) (\frac{{[2 p - 3]}_{q, 3}}{q^{2 p - 2} {[p - 2]}_{q, 2}}) & (σ_{2} ≦ μ ≦ σ_{1}) \\ (\frac{B - A}{2}) (\frac{{[2 p - 3]}_{q, 3}}{q^{2 p - 2} {[p - 2]}_{q, 2}}) Λ (q) & (μ < σ_{2}), \end{matrix}

where

Λ (q) = \frac{\{\begin{matrix} \{(1 + B q {[2 p - 2]}_{q} - A {[2 p - 1]}_{q}) (q + 1) - 2\} {[p - 1]}_{q} {[2 p - 3]}_{q} \\ + μ {(q + 1)}^{2} (A - B) {[2 p - 2]}_{q, 2} {[p - 2]}_{q} \end{matrix}\}}{2 {[p - 1]}_{q} {[2 p - 3]}_{q}},

σ_{1} = \frac{{[p - 1]}_{q} {[2 p - 3]}_{q} {4 + (q + 1) (A {[2 p - 1]}_{q} - q B {[2 p - 2]}_{q} - 1)}}{{(q + 1)}^{2} (A - B) {[p - 2]}_{q} {[2 p - 2]}_{q, 2}}

and

σ_{2} = \frac{{[p - 1]}_{q} {[2 p - 3]}_{q} {(q + 1) (A {[2 p - 1]}_{q} - 1 - q B {[2 p - 2]}_{q})}}{4 {(q + 1)}^{2} (A - B) {[p - 2]}_{q} {[2 p - 2]}_{q, 2}} .

Proof.

From the assumption of the theorem, we obtain

- \frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)} ≺ ϕ (z),

where

ϕ (z) = \frac{2 - q (1 - A) z + (1 + A) z}{2 - q (1 - B) z + (1 + B) z} .

This gives that

- \frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)} = ϕ (w (z)),

where

w (z)

is a Schwarz function. Now a function

h (z)

is defined as follows:

h (z) = \frac{1 + w (z)}{1 - w (z)} = 1 + \sum_{n = 1}^{\infty} h_{n} z^{n} \in P .

□

Furthermore, one can see that

\begin{matrix} ϕ (w (z)) = \frac{2 (h (z) + 1 - q (h (z) - 1)) + (1 + A) (q + 1) (h (z) - 1)}{2 (h (z) + 1 - q (h (z) - 1)) + (1 + B) (q + 1) (h (z) - 1)} \\ = 1 + \frac{1}{4} (1 + q) (A - B) h_{1} z + \frac{1}{16} (1 + q) (A - B) \{4 h_{2} - (B (1 + q) - q + 3) h_{1}^{2}\} z^{2} + \dots . \end{matrix}

Similarly, we find that

\begin{matrix} - \frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)} & = 1 - \frac{{[p - 1]}_{q}}{{[2 p - 2]}_{q, 2}} q^{p - 1} a_{1 - p} z \\ + \frac{{[p - 1]}_{q}}{{[2 (p - 1)]}_{q, 2}} q^{2 (p - 1)} (\frac{{[p - 1]}_{q}}{{[2 (p - 1)]}_{q}} a_{1 - p}^{2} - \frac{{[p - 2]}_{q}}{{[2 p - 3]}_{q}} (1 + q) a_{2 - p}) z^{2} + \dots \end{matrix}

for

p ≧ 2

. Therefore, for

p ≧ 2

, we obtain

a_{1 - p} = - \frac{(q + 1) (A - B) {[2 (p - 1)]}_{q, 2}}{4 q^{p - 1} {[p - 1]}_{q}} h_{1}

(14)

and

a_{2 - p} = \frac{(A - B) {[2 p - 3]}_{q, 3}}{q^{2 p - 2} {[p - 2]}_{q, 2}} (\frac{1}{16} k_{1} (q) h_{1}^{2} - \frac{1}{4} h_{2}),

(15)

where

k_{1} (q) = (1 + q) {A {[2 p - 1]}_{q} - B ({[2 p - 1]}_{q} - 1) - 1} + 4 .

(16)

Hence we obtain for

p ≧ 2

that

| a_{2 - p} - μ a_{1 - p}^{2} | = (\frac{A - B}{4}) (\frac{{[2 p - 3]}_{q, 3}}{q^{2 p - 2} {[p - 2]}_{q, 2}}) | h_{2} - k_{2} h_{1}^{2} |,

(17)

where

k_{2} = \frac{{[p - 1]}_{q} {[2 p - 3]}_{q} k_{1} (q) - μ {[2 (p - 1)]}_{q, 2} {[p - 2]}_{q} (A - B) {(q + 1)}^{2}}{4 {[2 p - 3]}_{q} {[p - 1]}_{q}}

with

k_{1} (q)

given by (16).

Now we can see that the conditions

μ > σ_{1}

,

σ_{2} ≦ μ ≦ σ_{1}

and

μ < σ_{2}

in Theorem 1 imply that

k_{2} < 0

,

0 ≦ k_{2} ≦ 1

and

k_{2} > 1

, respectively. By applying Lemma 1 in (17), the desired result is obtained. This proves Theorem 1.

Applying the same method as in the proof of Theorem 1, we obtain the following theorem for the case

p = 1

.

Theorem 2.

If

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1} \in M Σ_{q}^{*} [A, B],

then

| a_{1} - μ a_{0}^{2} | ≦ \{\begin{matrix} (\frac{A - B}{4}) [(1 - A) q + μ {(q + 1)}^{2} (A - B) - A - 1] & (μ > \frac{(A - 1) q + A + 3}{(A - B) {(q + 1)}^{2}}) \\ \frac{A - B}{2} & (\frac{A - 1}{(A - B) (q + 1)} ≦ μ ≦ \frac{(A - 1) q + A + 3}{(A - B) {(q + 1)}^{2}}) \\ (\frac{B - A}{4}) [(1 - A) q + μ {(q + 1)}^{2} (A - B) - A - 1] & (μ < \frac{A - 1}{(A - B) (q + 1)}) . \end{matrix}

Letting

q \to 1^{-}

,

A = 1

and

B = - 1

in Theorem 2, we obtain a result of the known family

M Σ^{*}

.

Corollary 1.

If

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1} \in M Σ^{*},

then

a_{1} - μ a_{0}^{2}| ≦ \{\begin{matrix} 4 μ - 1 & (μ > \frac{1}{2}) \\ 1 & (0 ≦ μ ≦ \frac{1}{2}) \\ 1 - 4 μ & (μ < 0) . \end{matrix}

Theorem 3.

Let

p ≧ 2

. If

g (z) = z^{- p} + \sum_{k = 1}^{\infty} a_{- p + k} z^{- p + k} \in M Σ_{q}^{*} [p, A, B],

then

|a_{- p + k}| ≦ \prod_{j = 1}^{k} \frac{2 {[j - 1]}_{q} + {[2 p - 1]}_{q} (q + 1) (A - B)}{2 {[j]}_{q} q^{p - 1} {[p - j]}_{q}}

(18)

for

1 ≦ k ≦ p - 1

.

Proof.

If g belongs to

M Σ_{q}^{*} [p, A, B]

, then

ψ (z) : = - \frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)} ≺ ϕ (z),

(19)

where

ϕ (z) = \frac{z (1 + A) - z q (1 - A) + 2}{z (1 + B) - z q (1 - B) + 2} = 1 - \frac{1}{2} (1 + q) (B - A) z + \frac{1}{4} (1 + q) (B - A) \{1 + B (1 + q) - q\} z^{2} + \dots .

□

Let

ψ (z) = 1 + \sum_{k = 1}^{\infty} ψ_{k} z^{k} .

Applying Lemma 2, we obtain

| ψ_{k} | ≦ \frac{1}{2} (q + 1) (A - B) (k ≧ 1) .

(20)

Furthermore, from (19), we have

- q^{2 p - 1} z (D_{q}^{(p)} g) (z) = {{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)} ψ (z),

which implies that

\begin{matrix} - q^{2 p - 1} (\sum_{k = 1}^{p} \frac{{(- 1)}^{p} {[k]}_{q, p}}{q^{p [k + \frac{1}{2} (p - 1)]}} a_{- k} z^{- p - k + 1} + \sum_{k = p}^{\infty} {[- p + k + 1]}_{q, p} a_{k} z^{- p + k + 1}) \\ = {[2 p - 1]}_{q} (1 + \sum_{k = 1}^{\infty} ψ_{k} z^{k}) (\sum_{k = 1}^{p} \frac{{(- 1)}^{p - 1} {[k]}_{q, p - 1}}{q^{[k + \frac{1}{2} (p - 2)] (p - 1)}} a_{- k} z^{- p - k + 1} \\ + \sum_{k = p - 1}^{\infty} {[2 + k - p]}_{q, p - 1} a_{k} z^{- p + k + 1}), \end{matrix}

where

a_{- p} = 1

.

It is easily seen from the above formula that

| a_{- p + k} | ≦ \frac{(A - B) (q + 1) {[2 p - 1]}_{q} q^{\frac{1}{2} (p - 1) (3 p - 2 k - 2)}}{2 {[k]}_{q} {[p - k]}_{q, p - 1}} \sum_{l = 1}^{k} \frac{{[p + l - k]}_{q, p - 1}}{q^{\frac{1}{2} (3 p - 2 k + 2 l - 2) (p - 1)}} |a_{k - p - l}|

(21)

for

1 ≦ k ≦ p - 1

.

Now

\begin{matrix} | a_{1 - p} | ≦ \frac{{[2 p - 2]}_{q, 2} (1 + q) (A - B)}{2 q^{p - 1} {[p - 1]}_{q}}, \\ | a_{2 - p} | ≦ \frac{q^{\frac{1}{2} (p - 1) (3 p - 6)} {[2 p - 1]}_{q} (1 + q) (A - B)}{2 {[p - 2]}_{q, p - 1} {[2]}_{q}} \{\frac{{[p]}_{q, p - 1}}{q^{\frac{1}{2} (3 p - 2) (p - 1)}} + \frac{{[p - 1]}_{q, p - 1}}{q^{\frac{1}{2} (3 p - 4) (p - 1)}} | a_{1 - p} |\} \\ = \frac{(1 + q) (A - B) {[2 p - 2]}_{q, 2}}{2 q^{p - 1} {[p - 1]}_{q}} \cdot \frac{{2 + {[2 p - 1]}_{q} (1 + q) (A - B)} {[2 p - 3]}_{q}}{2 q^{p - 1} {[2]}_{q} {[p - 2]}_{q}}, \\ \dots \dots \dots \\ | a_{k - p} | ≦ \prod_{j = 1}^{k} \frac{2 {[j - 1]}_{q} + (1 + q) (A - B) {[2 p - 1]}_{q}}{2 q^{p - 1} {[j]}_{q} {[p - j]}_{q}} \end{matrix}

for

1 ≦ k ≦ p - 1

. This proves Theorem 3.

Applying the same methods as in the proof of Theorem 3, we obtain the following Theorems 4 and 5.

Theorem 4.

Let

p ≧ 2

. If

g (z) = z^{- p} + \sum_{k = 1}^{\infty} a_{- p + k} z^{- p + k}

belongs to

M C_{q} [p, A, B],

then

| a_{- p + k} | ≦ \frac{{[p]}_{q, p}}{q^{p k} {[p - k]}_{q, p}} \prod_{n = 1}^{k} \frac{{[2 p - 1]}_{q} (1 + q) (A - B) + 2 {[n - 1]}_{q}}{2 {[n]}_{q} q^{p - 1} {[p - n]}_{q}}

for

1 ≦ k ≦ p - 1

.

Theorem 5.

Let

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1}

belong to

M Σ_{q}^{*} [A, B] .

Then

| a_{k - 1} | ≦ \prod_{n = 1}^{k} \frac{(1 + q) (A - B) + 2 {[n - 1]}_{q}}{2 {[n]}_{q}}

for

k ≧ 2

.

Letting

q \to 1 -

,

A = 1 - 2 α

(0 ≦ α < 1)

and

B = - 1

in Theorem 5, we have a result of the known family

M Σ^{*} (α)

.

Corollary 2.

Let

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1} \in M Σ^{*} (α) .

Then

| a_{k - 1} | ≦ \prod_{j = 1}^{k} \frac{j - 2 α + 1}{j}

for

k ≧ 2

.

The following equivalence could help us to study the family

M Σ_{q}^{*} [p, A, B]

:

g \in M Σ_{q}^{*} [p, A, B] ⟺ |\frac{(1 - B) \{\frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)}\} + (1 - A)}{(1 + B) (- \frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)}) - (1 + A)} - \frac{1}{1 - q}| < \frac{1}{1 - q} .

Theorem 6.

If a function

g (z) = z^{- p} + \sum_{k = 1}^{\infty} a_{- p + k} z^{- p + k} \in Σ (p)

satisfies

\begin{matrix} \sum_{k = 1}^{p} (\frac{{[k]}_{q, p - 1}}{q^{[k + \frac{1}{2} (p - 2)] (p - 1)}}) \{|{[2 p - 1]}_{q} (1 + A) - {[p + k - 1]}_{q} q^{p - k} (1 + B)| + 2 {[p - k]}_{q}\} | a_{- k} | \\ + \sum_{k = p}^{\infty} {[k - p]}_{q, p - 1} \{|{[2 p - 1]}_{q} (1 + A) - {[p + k - 1]}_{q} q^{2 p - 1} (1 + B)| + 2 {[k + p]}_{q}\} | a_{k} | \\ + {[2 p - 1]}_{q} {[p - 1]}_{q}! (2 + A) | a_{p - 1} | < \frac{(A - B) {[p]}_{q, p}}{q^{\frac{1}{2} (3 p - 2) (p - 1)}}, \end{matrix}

(22)

then

g \in M Σ_{q}^{*} [p, A, B]

.

Proof.

By a simple calculation, we obtain

\begin{matrix} |\frac{(1 - B) \{\frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)}\} + (1 - A)}{(1 + B) \{- \frac{q^{2 p - 1} z (D_{q}^{(p)} g) (z)}{{[2 p - 1]}_{q} (D_{q}^{(p - 1)} g) (z)}\} - (1 + A)} - \frac{1}{1 - q}| \\ ≦ |\frac{{- q^{2 p - 1} z (D_{q}^{(p)} g) (z)} (1 - B) - {[2 p - 1]}_{q} (1 - A) (D_{q}^{(p - 1)} g) (z)}{{- q^{2 p - 1} z (D_{q}^{(p)} g) (z)} (1 + B) - {[2 p - 1]}_{q} (1 + A) (D_{q}^{(p - 1)} g) (z)} + 1| + \frac{q}{1 - q} \\ = 2 |\frac{\{\begin{matrix} \sum_{k = 1}^{p} \frac{{(- 1)}^{p - 1} {[k]}_{q, p - 1} {[2 p - 1]}_{q}}{q^{(p - 1) [k + \frac{1}{2} (p - 2)]}} a_{- k} z^{p - k} + \sum_{k = p - 1}^{\infty} {[k + 2 - p]}_{q, p} {[2 p - 1]}_{q} a_{k} z^{k + p} \\ + \sum_{k = 1}^{p} \frac{{(- 1)}^{p} {[k]}_{q, p} q^{2 p - 1}}{q^{p [k + \frac{1}{2} (p - 1)]}} a_{- k} z^{p - k} + \sum_{k = p}^{\infty} q^{2 p - 1} {[k + 1 - p]}_{q, p} a_{k} z^{n + p} \end{matrix}\}}{\{\begin{matrix} (A - B) \frac{{(- 1)}^{p - 1} {[p]}_{q, p}}{q^{\frac{1}{2} (p - 1) (3 p - 2)}} + (A + 1) {[p - 1]}_{q}! {[2 p - 1]}_{q} a_{p - 1} z^{2 p - 1} \\ + \sum_{k = 1}^{p - 1} \frac{{(- 1)}^{p - 1} {[k]}_{q, p - 1}}{q^{(p - 1) [k + \frac{1}{2} (p - 2)]}} {{[2 p - 1]}_{q} (A + 1) - (1 + B) q^{p - k} {[p - 1 + k]}_{q}} a_{- k} z^{p - k} \\ + \sum_{k = p}^{\infty} {{[2 p - 1]}_{q} (A + 1) - (B + 1) q^{2 p - 1} {[p - 1 + k]}_{q}} {[k - p]}_{q, p + 1} a_{k} z^{k + p} \end{matrix}\}}| \\ + \frac{q}{1 - q} \\ ≦ 2 \frac{\sum_{k = 1}^{p - 1} \frac{{[k]}_{q, p - 1} {[p - k]}_{q}}{q^{(p - 1) [k + \frac{1}{2} (p - 2)]}} | a_{- k} {| + [p - 1]}_{q}! {[2 p - 1]}_{q} | a_{p - 1} | + \sum_{k = p}^{\infty} {[k - p]}_{q, p + 1} {[k + p]}_{q} | a_{k} |}{\{\begin{matrix} (\frac{{[p]}_{q, p}}{q^{\frac{1}{2} (p - 1) (3 p - 2)}} (A - B) - (1 + A) {[p - 1]}_{q}! {[2 p - 1]}_{q} | a_{p - 1} |) \\ - \sum_{k = 1}^{p - 1} \frac{{[k]}_{q, p - 1}}{q^{[k + \frac{1}{2} (p - 2)] (p - 1)}} |\{{[2 p - 1]}_{q} (A + 1) - (B + 1) {[p + k - 1 +]}_{q} q^{p - k}\}| | a_{- k} | \\ - \sum_{k = p}^{\infty} {[k - p]}_{q, p + 1} |\{{[2 p - 1]}_{q} (A + 1) - (B + 1) q^{2 p - 1} {[p + k - 1]}_{q}\}| | a_{k} | \end{matrix}\}} + \frac{q}{1 - q} . \end{matrix}

(23)

□

Now, it follows from (22) that the last expression in (23) is less than

\frac{1}{1 - q}

. This proves Theorem 6.

Theorem 7.

If a function

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1} \in Σ

satisfies

\sum_{k = 1}^{\infty} \{2 {[k]}_{q} + |q {[k - 1]}_{q} (1 + B) - (1 - A)|\} | a_{k - 1} | < A - B,

(24)

then

g \in M Σ_{q}^{*} [A, B]

.

Proof.

By simple calculation, we have

\begin{matrix} |\frac{(1 - B) (\frac{q z (D_{q} g) (z)}{g (z)}) + (1 - A)}{(1 + B) (- \frac{q z (D_{q} g) (z)}{g (z)}) - (1 + A)} - \frac{1}{1 - q}| \\ ≦ \frac{q}{1 - q} + 2 |\frac{g (z) + q z (D_{q} g) (z)}{q (1 + B) z (D_{q} g) (z) + (1 + A)}| \\ = \frac{q}{1 - q} + 2 |\frac{\sum_{k = 1}^{\infty} {[k]}_{q} | a_{k - 1} |}{(A - B) - \sum_{k = 1}^{\infty} [q (1 + B) {[k - 1]}_{q} + (1 + A)] | a_{k - 1} |}| . \end{matrix}

(25)

From (24) we can see that (25) is less than

\frac{1}{1 - q}

. This proves Theorem 7. □

Letting

A = 1 - 2 α

(0 ≦ α < 1)

,

B = - 1

and

q \to 1^{-}

in Theorem 7, we obtain a result of the known family

M Σ^{*} (α)

.

Corollary 3.

If a function

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1} \in Σ

satisfies

\sum_{k = 1}^{\infty} (1 + k - α) | a_{k - 1} | < 1 - α (0 ≦ α < 1),

then

g \in M Σ^{*} (α)

.

Applying the same method as in the proof of Theorem 7, we obtain the following theorem.

Theorem 8.

If a function

g (z) = z^{- 1} + \sum_{k = 1}^{\infty} a_{k - 1} z^{k - 1} \in Σ

satisfies

\sum_{k = 1}^{\infty} \{2 {[k]}_{q} + |q {[k - 1]}_{q} (1 + B) - (1 - A)|\} {[k - 1]}_{q} | a_{k - 1} | < A - B,

then

g \in M C_{q} [A, B] .

Author Contributions

Every authors contribution is equal. All authors have read and agreed to the published version of the manuscript.

Funding

The work was supported by Natural Science Foundation of Nanjing Vocational College of Information Technology (Grant No.YK20180403).

Data Availability Statement

Not applicable.

Acknowledgments

The authors thank the referees for their careful reading and suggestions.

Conflicts of Interest

The authors declare no conflict of interest.

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Liu, L.; Srivastava, R.; Liu, J.-L. Applications of Higher-Order q-Derivative to Meromorphic q-Starlike Function Related to Janowski Function. Axioms 2022, 11, 509. https://doi.org/10.3390/axioms11100509

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Liu L, Srivastava R, Liu J-L. Applications of Higher-Order q-Derivative to Meromorphic q-Starlike Function Related to Janowski Function. Axioms. 2022; 11(10):509. https://doi.org/10.3390/axioms11100509

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Liu, Likai, Rekha Srivastava, and Jin-Lin Liu. 2022. "Applications of Higher-Order q-Derivative to Meromorphic q-Starlike Function Related to Janowski Function" Axioms 11, no. 10: 509. https://doi.org/10.3390/axioms11100509

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Applications of Higher-Order q-Derivative to Meromorphic q-Starlike Function Related to Janowski Function

Abstract

1. Introduction

2. Main Results

Author Contributions

Funding

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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