Startseite A new family of multivalent functions defined by certain forms of the quantum integral operator
Artikel Open Access

A new family of multivalent functions defined by certain forms of the quantum integral operator

  • Ajmal Khan , Isra Al-shbeil EMAIL logo , Amani Shatarah , Norah Mousa Alrayes , Shahid Khan und Wasim ul Haq
Veröffentlicht/Copyright: 29. Juli 2025
Artikel downloaden (PDF)
Veröffentlichen auch Sie bei De Gruyter Brill
Informationen für Autor*innen Erkunden Sie dieses Fachgebiet
Demonstratio Mathematica
Aus der Zeitschrift Demonstratio Mathematica Band 58 Heft 1

Abstract

In this work, using the concepts of q -calculus, we first define the q -Jung-Kim-Srivastava and q -Bernardi integral operators for multivalent functions. Then, we use these operators to establish the generalized integral operator q , p m λ f ( z ) for multivalent functions. By using the newly defined operator q , p m λ f ( z ) , we define a new class of multivalent analytic functions and diskuss various interesting features of the functions belonging to this class. Certain interesting examples of our developments are also considered. Furthermore, we explore the applications of the Carathéodory lemma in the form of specific results.

Keywords: analytic functions; q-Bernardi integral operator; multivalent analytic functions; q-difference operator; fractional q-integral operator; q-Jack’s lemma
MSC 2010: 30C45; 30C50; 11B65; 47B38

1 Introduction and definitions

Differential and integral operators have been the focus of study since the beginning of analytic function theory, when Alexander [1] presented the first integral operator in 1915. Differential and integral operators are continually being combined in new and interesting ways (for examples, see [2,3]). Recent studies of differential and integral operators from a wide range of ideas, including quantum calculus, have produced incredible findings with broad implications for physics and mathematics. A new survey-cum-expository review research [4] focuses on several intriguing applications of differential and integral operators.

The study of geometric functions gained influence from the theory of real and complex-order integrals and derivatives, which also demonstrated potential in mathematical modeling and analysis of real-world problems in the applied sciences. Examples of works that fall within the aforementioned area include an analysis of the dynamics of dengue transmission [5] and a new model of the human liver [6]. Particularly significant for the study of both pure and practical mathematics is the family of integral operators associated with the first-kind Lommel functions, which was presented in [7]. Because of differential and integral operators, functional analysis and operator theory may be used in the study of differential equations. In order to solve differential equations using the operator method, we make use of the properties of differential operators, and it can be demonstrated that such operators are involved in the solution of partial differential equations; however, this requires further research. A number of intriguing geometric and mapping properties are derived for the integral operators given here.

We suppose that class includes a set of analytic functions f ( z ) in open unit disk

E = { z C : z < 1 }

and takes the form given by

(1) f ( z ) = z + j = 2 a j z j .

Let ( p ) contain multivalent functions f ( z ) in the open unit disk E = { z C : z < 1 } and of the form

(2) f ( z ) = z p + k = p + j a k z k , p , j N = { 1 , 2 , 3 } .

Numerous mathematicians, physicists, and engineers have devoted a great deal of effort and time to studying the standard quantum calculus, and the field has benefited much from its practical applications in fields as diverse as engineering, economics, mathematics, and others (see, for example, [811]). Taking into consideration the aforementioned information concerning q -calculus, it is reasonable to conclude that, over the last three decades, q -calculus has served as the bridge between mathematics and physics. Remarkably, the q -calculus operator, q -integral operator, and q -derivative operator are used to construct several classes of regular functions and find applications in many areas of mathematics, including general relativity, the calculus of variations, orthogonal polynomials, and fundamental hypergeometric functions. The q -derivative and q -integral were defined by Jackson [12] and were the first to be used. Purohit [13] was the first mathematician who used certain fractional q -derivative operators, to introduce and examine the class of multivalent functions in an open unit disk. He made a significant contribution by giving q -extension to a number of findings in analytic function theory. In a book chapter (see, for details, [14] pp. 347 et seq.; see also [15]) by Srivastava, the basic (or q -) hypergeometric functions were used for the first time in geometric function theory (GFT) and also provided a highly significant utilization of the q -calculus in the context of GFT. Ismail [16] earlier introduced a class of q -starlike functions by using the q -differential operator. Some differential equations were solved using the q -derivative by Akça et al. [17]. This study also makes use of q -calculus and introduces many new, significant q -analogs of differential and integral operators. The q -operators are defined with a number of interesting consequences by using the convolution of normalized analytic functions in the field of GFT (see [18,19]). By utilizing the idea of fractional q -calculus, Selvakumaran et al. [20] recently presented the q -integral operator for particular analytic functions in the open unit disk. They also investigated the various convexity characteristics in [20] for certain classes of analytic functions formed by a linear multiplier and a fractional q -differential integral operator. Serivastava et al. [21] defined a new fractional differintegral operator by subordination and diskussed how it relates to several classes of analytic functions. Also, some recent findings and studies related to the q -derivatives and q -integral operators have been presented (see, for example, [22,23,24,25,26,27,28,29]).

The following is the definition of the quantum difference operator, also known as the q -derivative operator:

Definition 1

[12]. Let f , the q -difference operator ( q -derivative operator) is defined is as follows:

(3) q f ( z ) = f ( z ) f ( q z ) ( 1 q ) z , z 0 , q ( 0 , 1 ) .

Using (1) in (3), and after some simple calculations, we obtain the series form of the q -difference operator as

q f ( z ) = 1 + j = 2 [ j ] q a j z j 1 , z E ,

where

(4) [ j ] q = 1 q j 1 q , q ( 0 , 1 ) .

We note that, for q 1

q f ( z ) f ( z )

and

q f ( 0 ) = f ( 0 ) .

More specifically,

(5) q z j = [ j ] q z j 1 .

When q 1 , then

[ j ] q j .

Remark 1

Similarly using (2) in (3), then we have the following series form for f ( p ) :

q f ( z ) = [ p ] q z p 1 + k = p + j [ k ] q a k z k 1 , p , j N = { 1 , 2 , 3 , } .

Definition 2

The definition of the q -gamma function Γ q is

(6) Γ q ( x ) = ( 1 q ) 1 x j = 0 1 q j + 1 1 q j + x , x > 0 ,

which contains the following properties:

(7) Γ q ( x + 1 ) = [ x ] q Γ q ( x )

and

(8) Γ q ( x + 1 ) = [ x ] q !

where x N and [ x ] q ! are defined as

(9) [ x ] q ! = [ x ] q [ x 1 ] q [ 2 ] q [ 1 ] q if x N 1 if x = 0 .

Definition 3

The q -beta function B q is defined as

(10) B q ( v 0 , v 1 ) = 0 1 x v 0 1 ( 1 q x ) q v 1 d q x , ( v 0 , v 1 > 0 , 0 < q < 1 )

and

(11) B q ( v 0 , v 1 ) = Γ q ( v 0 ) Γ q ( v 1 ) Γ q ( v 0 + v 1 ) ,

where Γ q is given by (6).

The purpose of this article is to construct a new q -analogous integral operator for multivalent functions by combining the strengths of the q -Jung-Kim-Srivastava and q -Bernardi integral operators and subsequently investigate its applications and implications.

We begin by introducing the q -Bernardi integral operator for multivalent functions, which is defined as follows:

Definition 4

For functions f ( z ) ( p ) , we define the expression q , p 1 f ( z )

(12) q , p 1 f ( z ) = [ p + γ ] q z γ 0 z t γ 1 f ( t ) d q t = z p + k = p + j [ p + γ ] q [ k + γ ] q a k z k , γ > 1 , p , j N .

We consider

q , p 2 f ( z ) = q , p 1 ( q , p 1 f ( z ) ) = z p + k = p + j [ p + γ ] q [ k + γ ] q 2 a k z k , γ > 1 , j N .

Similarly, continuing this process, we obtain the generalizations of the q -Bernardi integral operator for multivalent functions:

(13) q , p m f ( z ) = q , p 1 ( q , p m + 1 f ( z ) ) = z p + k = p + j [ p + γ ] q [ k + γ ] q m a k z k , γ > 1 , j N ,

where m N and q , p 0 f ( z ) = f ( z ) .

Remark 2

For m = 1 , and p = 1 , in (12), then we obtain the q -Bernardi integral operator for f , and defined in [30] as follows:

(14) q 1 f ( z ) = [ 1 + γ ] q z γ 0 z t γ 1 f ( t ) d q t = z + k = j + 1 [ 1 + γ ] q [ k + γ ] q a k z k , γ > 1 , j N .

Remark 3

For q 1 and p = 1 , in (12), then we have the Bernardi integral operator for f and given in [31] and defined as follows:

(15) 1 f ( z ) = 1 + γ z γ 0 z t γ 1 f ( t ) d t = z + k = j + 1 1 + γ k + γ a k z k , γ > 1 , j N .

Remark 4

Furthermore, taking p = 1 , γ = 1 , and q 1 in (12) for f ( z ) , we have the Libera integral operator given in [32].

Definition 5

[33] For λ > 0 , the fractional q -integral operator is defined as

D q λ f ( z ) = 1 Γ q ( λ ) 0 z 1 ( z t q ) 1 λ f ( t ) d q ( t )

and ( z t q ) 1 λ is defined by

( z t q ) 1 λ = z 1 λ Φ 0 1 ( q λ + 1 , , q , t q λ z ) .

The representation of series Φ 0 1 is given by

Φ 0 1 ( a , , q , z ) = 1 + j = 1 ( a , q ) j ( q , q ) j z j , ( q < 1 , z < 1 ) ,

where

( a , q ) j = k = 0 j 1 ( 1 a q k ) , j N .

With the above definitions, and for the function of the form (2), we know that

D q λ f ( z ) = Γ q ( p + 1 ) Γ q ( p + 1 + λ ) z p + λ + k = j + p Γ q ( k + 1 ) Γ q ( k + 1 + λ ) a k z k + λ

for λ > 0 , and f ( z ) ( p ) .

Definition 6

Using the fractional q -integral operator for f ( p ) , we define the q -Jung-Kim-Srivastava integral operator as follows:

(16) q , p λ f ( z ) = Γ q ( p + γ + λ ) Γ q ( p + γ ) z 1 γ λ D q λ ( z γ 1 f ( z ) ) = z p + k = p + j Γ q ( p + γ + λ ) Γ q ( k + γ ) Γ q ( p + γ ) Γ q ( k + γ + λ ) a k z k ,

where 0 λ 1 , and γ > 1 .

Remark 5

(i) For p = 1 and q 1 in (16), we obtain the Jung-Kim-Srivastava integral operator for f defined in [34] as

λ f ( z ) = z + k = j + 1 Γ ( j + γ ) Γ ( 1 + γ + λ ) Γ ( j + γ + λ ) Γ ( 1 + γ ) a k z k ,

where 0 λ 1 , j N , and γ > 1 .

(ii) If λ = 0 , in (16), then 0 f ( z ) = f ( z ) , and if λ = 1 , in (16), then we have the q -Bernardi integral operator for f ( p ) given by (12).

(iii) For q 1 , λ = 1 and p = 1 , then we have the Bernardi integral operator for f defined by Bernardi [30].

Definition 7

Using the operator q , p λ f ( z ) given by (16) and q , p m f ( z ) defined in (13), we define the operator q , p m λ f ( z ) as follows:

(17) q , p m λ f ( z ) = q , p m ( q , p λ f ( z ) ) = z p + k = p + j [ p + γ ] q [ k + γ ] q m Γ q ( k + γ ) Γ q ( p + γ + λ ) Γ q ( k + γ + λ ) Γ q ( p + γ ) a k z k ,

where 0 λ 1 , γ > 1 , and m N .

Remark 6

(i) The operator q , p m λ f ( z ) is the generalized form of the q -Bernardi integral and q -Jung-Kim-Srivastava integral operator.

(ii) The following identity can be easily satisfied for the operator q , p m λ f ( z ) :

(18) q , p m λ + 1 f ( z ) = [ γ ] q [ p + γ ] q q , p m λ f ( z ) + q γ [ p + γ ] q z q ( q , p m λ f ( z ) ) .

(iii) From the definition q , p m λ f ( z ) , we observe that

q , p m λ f ( z ) = q , p m ( q , p λ f ( z ) ) = q , p λ ( q , p m f ( z ) ) .

(iv) For s different boundary points z l , l = 1 , 2 , 3 , , s , with z l = 1 , we assume

(19) α s = 1 s l = 1 s q , p m λ f ( z l ) z l p ,

where

α s e i β q , p m λ f ( E ) ,

α s 1 , π 2 β π 2

and E is the open unit disk.

Definition 8

Let π 2 β π 2 , ρ > 0 , λ > 0 , γ > 1 , and m N . If f ( z ) ( p ) satisfies

(20) e i β ( q , p m λ f ( z ) ) z p α s e i β α s 1 < ρ , z E ,

then f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

Class T p , j ( q , α s , β , ρ , λ , m ) represented by the function f ( z ) ( p ) under the assumption

(21) q , p m λ f ( z ) z p 1 < ρ e i β α s , z E ,

is satisfied. If we consider the function f ( z ) ( p ) given by

(22) f ( z ) = z p + [ p + j + γ ] q [ k + γ ] q m Γ q ( p + γ ) Γ q ( p + j + γ + λ ) Γ q ( p + j + γ ) Γ q ( p + γ + λ ) ρ ( e i β α s ) z p + j ,

where k = j + 1 , and j N , then f ( z ) satisfies

(23) q , p m λ f ( z ) z p 1 = ρ e i β α s z j < ρ e i β α s , z E .

Hence, f ( z ) from (22) belongs to the class T p , j ( q , α s , β , ρ , λ , m ) .

In order to diskuss our problems with f ( z ) T p , j ( q , α s , β , ρ , λ , m ) , we must first consider the following q -Jack’s lemma proved by Çetinkaya and Polatoĝlu (see [35], Lemma 2.3, page 818).

Lemma 1

[35] Let u ( z ) be analytic in the unit disk E, with u ( 0 ) = 0 . If u ( z ) attains its maximum value on the circle. z = r at a point z 0 E , then

(24) z 0 q u ( z 0 ) u ( z 0 ) = j .

This article is structured into four sections. Section 1 provides a foundation by reviewing key concepts in GFT and examining applications of existing differential and integral operators. It also introduces innovative q -analogs of integral operators for multivalent functions and defines new classes of multivalent functions using the generalized operator q , p m λ f ( z ) , which is vital for our main diskoveries. Section 2 presents the core results supported by examples that illustrate their practical applications. Section 3 leverages the Carathéodory lemma to derive additional results. Section 4 offers concluding thoughts, distilling the essential insights from our investigation.

2 Main results and examples for class T p , j ( q , α s , β , ρ , λ , m )

In order to make a function f a member of T p , j ( q , α s , β , ρ , λ , m ) , we first investigate a sufficient condition for it.

Theorem 1

If f ( z ) ( p ) satisfies

(25) q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 < q γ e i β α s j ρ [ p + γ ] q ( 1 + e i β α s ρ ) , z E ,

for some α s given by (19) with α s 1 such that z l E ( l = 1 , 2 , 3 , , s ), and for some real ρ > 1 , then

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E

that is f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

Proof

Let the function u ( z ) defined by

(26) u ( z ) = e i β ( q , p m λ f ( z ) ) z p α s e i β α s 1 = e i β e i β α s k = p + j [ p + γ ] q [ k + γ ] q m Γ q ( k + γ ) Γ q ( p + γ + λ ) Γ q ( k + γ + λ ) Γ q ( p + γ ) a k z k p .

Then

(27) q , p m λ f ( z ) z p = 1 + ( 1 e i β α s ) u ( z ) .

Using identity (18), we have

(28) q , p m λ + 1 f ( z ) = [ γ ] q [ p + γ ] q q , p m λ f ( z ) + q γ [ p + γ ] q z q ( q , p m λ f ( z ) ) .

Divided both sides of (28) by q , p m λ f ( z ) , and using the fact, [ γ ] q + q γ [ p ] q = [ p + γ ] q , we have

(29) q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 = q γ ( 1 e i β α s ) z q u ( z ) [ p + γ ] q ( 1 + ( 1 e i β α s ) u ( z ) ) .

Taking the modulus on both sides of (29), we have

q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 = q γ [ p + γ ] q ( 1 e i β α s ) z q ( u ( z ) ) ( 1 + ( 1 e i β α s ) u ( z ) ) < q γ e i β α s j ρ [ p + γ ] q ( 1 + e i β α s ρ )

by employing (25). Assume, to arrive at a contradiction, that there exists a point z 0 , ( 0 < z 0 < 1 ) such that

max { u ( z ) ; z z 0 } = u ( z 0 ) = ρ > 1 .

Then, we can write that u ( z 0 ) = ρ e i θ , ( 0 θ 2 π ) and z 0 q u ( z 0 ) = k u ( z 0 ) , k j by Lemma 1. For the point z 0 E , we have

q , p m λ + 1 f ( z 0 ) q , p m λ f ( z 0 ) 1 = q γ [ p + γ ] q ( 1 e i β α s ) z 0 q u ( z 0 ) ( 1 + ( 1 e i β α s ) u ( z 0 ) ) = q γ [ p + γ ] q ( 1 e i β α s ) k ρ ( 1 + ( 1 e i β α s ) ρ e i θ ) q γ 1 e i β α s j ρ [ p + γ ] q ( 1 + 1 e i β α s ρ ) = q γ e i β α s j ρ [ p + γ ] q ( 1 + e i β α s ρ ) .

Since this contradicts our condition (25), we see that there is no z 0 , ( 0 < z 0 < 1 ) such that

u ( z 0 ) = ρ > 1 .

This shows us that

u ( z ) = e i β ( q , p m λ f ( z ) ) z p 1 e i β α s < ρ ,

that is,

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E .

The theorem has now been proven.□

Example 1

Using the function f ( z ) ( p ) provided by

(30) f ( z ) = z p + a p + j z p + j , z E , j N ,

with 0 < a p + j < 1 2 T ( γ , λ , q ) , where

(31) T ( γ , λ , q ) = [ p + γ ] q [ p + j + γ ] q m Γ q ( p + j + γ ) Γ q ( p + γ + λ ) Γ q ( p + j + γ + λ ) Γ q ( p + γ ) .

For such f ( z ) , we have

q , p m λ + 1 f ( z ) q , p m λ f ( z ) = 1 + [ p + j + γ ] q [ p + γ ] q T ( γ , λ , q ) a p + j z j 1 + T ( γ , λ , q ) a p + j z j .

Taking modulus, we have

q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 < [ p + j + γ ] q [ p + γ ] q 1 T ( γ , λ , q ) a p + j 1 T ( γ , λ , q ) a p + j , z E .

We now take into account five boundary points so that

z 1 = e i arg ( a p + j ) j , z 2 = e i π 6 arg ( a p + j ) 6 j , z 3 = e i π 4 arg ( a p + j ) 4 j z 4 = e i π 3 arg ( a p + j ) 3 j , z 5 = e i π 2 arg ( a p + j ) 2 j .

We know that for these five boundary points

q , p m λ f ( z 1 ) z 1 p = 1 + T ( γ , λ , q ) a p + j e i arg ( a p + j ) = 1 + T ( γ , λ , q ) a p + j ,

q , p m λ f ( z 2 ) z 2 p = 1 + T ( γ , λ , q ) a p + j e i π 6 arg ( a p + j ) = 1 + ( 3 + i ) 2 T ( γ , λ , q ) a p + j ,

q , p m λ f ( z 3 ) z 3 p = 1 + T ( γ , λ , q ) a p + j e i π 4 arg ( a p + j ) = 1 + 2 ( 1 + i ) 2 T ( γ , λ , q ) a p + j ,

q , p m λ f ( z 4 ) z 4 p = 1 + T ( γ , λ , q ) a p + j e i π 3 arg ( a p + j ) = 1 + ( 1 + 3 i ) 2 T ( γ , λ , q ) a p + j ,

and

q , p m λ f ( z 5 ) z 5 p = 1 + T ( γ , λ , q ) a p + j e i π 2 arg ( a p + j ) = 1 + i T ( γ , λ , q ) a p + j .

Thus, from (19), we obtain α 5 and is given by

α 5 = 1 5 q , p m λ f ( z 1 ) z 1 p + q , p m λ f ( z 2 ) z 2 p + q , p m λ f ( z 3 ) z 3 p + q , p m λ f ( z 4 ) z 4 p + q , p m λ f ( z 5 ) z 5 p = 1 + ( 1 + i ) ( 3 + 2 + 3 ) 10 T ( γ , λ , q ) a p + j .

This gives us that

1 e i β α 5 = 2 ( 3 + 2 + 3 ) 10 T ( γ , λ , q ) a p + j .

For such α 5 and β , we take ρ > 1 with

[ p + j + γ ] q [ p + γ ] q 1 T ( γ , λ , q ) a p + j 1 T ( γ , λ , q ) a p + j q γ e i β α 5 j ρ [ p + γ ] q ( 1 + e i β α 5 ρ ) .

It follows from the above that

ρ 10 2 ( 3 + 2 + 3 ) ( 1 2 T ( γ , λ , q ) a p + j ) > 10 2 ( 3 + 2 + 3 ) > 1 .

For such α 5 and ρ > 1 , f ( z ) satisfies

q , p m λ f ( z ) z p 1 = T ( γ , λ , q ) a p + j < ρ e i β α 5 , z E .

Theorem 2

If f ( z ) ( p ) satisfies

(32) q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 q , p m λ f ( z ) z p 1 < q γ e i β α s 2 j ρ 2 [ p + γ ] q ( 1 + e i β α s ρ ) , z E ,

for some α s given by (19), with α s 1 such that z l E ( l = 1 , 2 , 3 , , s ), and for some real ρ > 1 , then

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E ,

that is f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

Proof

Given u ( z ) in (26). Using (27) and (29), we have

q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 q , p m λ f ( z ) z p 1 = q γ [ p + γ ] q ( 1 e i β α s ) 2 z u ( z ) q u ( z ) ( 1 + ( 1 e i β α s ) u ( z ) ) .

We suppose that there exists a point z 0 , ( 0 < z 0 < 1 ) such that

max { u ( z ) ; z z 0 } = u ( z 0 ) = ρ > 1 .

Then, we can write that

u ( z 0 ) = ρ e i θ , ( 0 θ 2 π )

and

z 0 q u ( z 0 ) = k u ( z 0 ) , k j

by Lemma 1. From the above, it follows that

q , p m λ + 1 f ( z 0 ) q , p m λ f ( z 0 ) 1 q , p m λ f ( z 0 ) z 0 p 1 = q γ [ p + γ ] q ( 1 e i β α s ) 2 z 0 u ( z 0 ) q u ( z 0 ) ( 1 + ( 1 e i β α s ) u ( z 0 ) ) q γ [ p + γ ] q e i β α s 2 ρ 2 j 1 + ( e i β α s ) ρ .

This is opposite to our condition (32) for f ( z ) . Thus, there is no z 0 , ( 0 < z 0 < 1 ) such that

u ( z 0 ) = ρ > 1 .

This means that

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E .

Example 2

Take a function f ( z ) defined by (30) with 0 < a p + j < 1 T ( γ , λ , q ) , where T ( γ , λ , q ) is defined by (31). For this function f ( z ) , we have

q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 q , p m λ f ( z ) z p 1 = q γ [ p + j + γ ] q [ p + γ ] q 1 T 2 ( γ , λ , q ) a p + j 2 z 2 j ( 1 + T ( γ , λ , q ) a p + j z j ) [ p + γ ] q < q γ [ p + j + γ ] q [ p + γ ] q 1 T 2 ( γ , λ , q ) a p + j 2 ( 1 T ( γ , λ , q ) a p + j ) [ p + γ ] q , z E .

Consider five boundary points

z 1 = e i arg ( a p + j ) j , z 2 = e i π 6 arg ( a p + j ) 6 j , z 3 = e i π 4 arg ( a p + j ) 4 j z 4 = e i π 3 arg ( a p + j ) 3 j , z 5 = e i π 2 arg ( a p + j ) 2 j .

We know about these five boundary points

q , p m λ f ( z 1 ) z 1 p = 1 + T ( γ , λ , q ) a p + j e i arg ( a p + j ) = 1 + T ( γ , λ , q ) a p + j ,

q , p m λ f ( z 2 ) z 2 p = 1 + T ( γ , λ , q ) a p + j e i π 6 arg ( a p + j ) = 1 + 3 + i 2 T ( γ , λ , q ) a p + j ,

q , p m λ f ( z 3 ) z 3 p = 1 + T ( γ , λ , q ) a p + j e i π 4 arg ( a p + j ) = 1 + 2 ( 1 + i ) 2 T ( γ , λ , q ) a p + j ,

q , p m λ f ( z 4 ) z 4 p = 1 + T ( γ , λ , q ) a p + j e i π 3 arg ( a p + j ) = 1 + ( 1 + 3 i ) 2 T ( γ , λ , q ) a p + j ,

and

q , p m λ f ( z 5 ) z 5 p = 1 + T ( γ , λ , q ) a p + j e i π 2 arg ( a p + j ) = 1 + i T ( γ , λ , q ) a p + j .

Thus, from (19), we obtain α 5 and is given by

α 5 = 1 5 q , p m λ f ( z 1 ) z 1 p + q , p m λ f ( z 2 ) z 2 p + q , p m λ f ( z 3 ) z 3 p + q , p m λ f ( z 4 ) z 4 p + q , p m λ f ( z 5 ) z 5 p

= 1 + ( 1 + i ) ( 3 + 2 + 3 ) 10 T ( γ , λ , q ) a p + j .

This gives us that

1 e i β α 5 = 2 ( 3 + 2 + 3 ) 10 T ( γ , λ , q ) a p + j .

For such α 5 and β , we take ρ > 1 with

q γ [ p + j + γ ] q [ p + γ ] q 1 T 2 ( γ , λ , q ) a p + j 2 [ p + γ ] q ( 1 T ( γ , λ , q ) a p + j ) q γ e i β α 5 2 j ρ 2 [ p + γ ] q ( 1 + e i β α 5 ρ ) .

It follows from the above that

ρ 10 2 ( 3 + 2 + 3 ) T ( γ , λ , q ) a p + j > 1 .

For α 5 and ρ > 1 , f ( z ) satisfies

q , p m λ f ( z ) z p 1 < ρ e i β α 5 , z E .

Theorem 3

If f ( z ) ( p ) satisfies

q , p m λ + l f ( z ) z p 1 < ρ 1 + j [ p + γ ] q e i β α s , z E .

For some α s given by (19), with α s 1 , ( l = 1 , 2 , 3 , , s ), and for some real ρ > 1 , then

q , p m λ + l 1 f ( z ) z p 1 < ρ e i β α s , z E .

Proof

Define the function u ( z ) by

u ( z ) = e i β ( q , p m λ + l 1 f ( z ) ) z p α s e i β α s 1 = e i β e i β α s k = p + j [ p + γ ] q [ k + γ ] q m l + 1 Γ q ( k + γ ) Γ q ( p + γ + λ ) Γ q ( k + γ + λ ) Γ q ( p + γ ) a k z k p .

Then, for u ( z ) given in (1) and

q , p m λ + l 1 f ( z ) = z p + ( 1 e i β α s ) z p u ( z ) .

By the definition of q , p m λ + l f ( z ) , we know that

q , p m λ + l f ( z ) = z 1 γ [ p + γ ] q q ( z γ q , p m λ + l 1 f ( z ) ) = z p 1 + ( 1 e i β α s ) u ( z ) 1 + z q u ( z ) [ p + γ ] q u ( z ) .

Our condition implies that

(33) q , p m λ + l f ( z ) z p 1 = ( 1 e i β α s ) u ( z ) 1 + z q u ( z ) [ p + γ ] q u ( z ) < ρ e i β α s 1 + j [ p + γ ] q

for all z E . Let there exist a point z 0 , ( 0 < z 0 < 1 ) such that

max { u ( z ) ; z z 0 } = u ( z 0 ) = ρ > 1 .

Then, by Lemma 1, we can write that u ( z 0 ) = ρ e i θ , ( 0 θ 2 π ) , and z 0 q u ( z 0 ) = k u ( z 0 ) , k j . Therefore, we have

q , p m λ + l f ( z 0 ) z 0 p 1 = ( 1 e i β α s ) u ( z 0 ) 1 + z 0 q u ( z 0 ) [ p + γ ] q u ( z 0 ) ρ e i β α s 1 + j [ p + γ ] q ,

which contradicts inequality (33). This means that there is no z 0 E , such that

u ( z 0 ) = ρ > 1 .

As we know that

u ( z ) = e i β ( q , p m λ + l 1 f ( z ) ) z p α s e i β α s 1 = e i β e i β α s q , p m λ + l 1 f ( z ) z p 1 < ρ .

Thus, our theorem is completed.□

Theorem 4

If f ( z ) ( p ) satisfies

(34) q , p m λ + l f ( z ) z p 1 < ρ 1 + j [ p + γ ] q l e i β α s , z E ,

for some α s defined by, (19) with α s 1 , ( l = 1 , 2 , 3 , , s ), and for ρ > 1 , then

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E ,

or, equivalently, f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

Proof

Theorem 3 demonstrates that if f ( z ) satisfy inequality (34), then

q , p m λ + l 1 f ( z ) z p 1 < ρ e i β α s 1 + j [ p + γ ] q l 1 , z E .

Similarly, we have

q , p m λ + l 2 f ( z ) z p 1 < ρ e i β α s 1 + j [ p + γ ] q l 2 , z E .

Considering this further, we obtain that

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E .

This completes the theorem.□

Example 3

For f ( z ) ( p ) provided by

f ( z ) = z p + a p + j z p + j , z E ,

which satisfies

(35) q , p m λ + l f ( z ) = z p + [ p + γ ] q [ p + j + γ ] q m l Γ q ( p + j + γ ) Γ q ( p + γ + λ ) Γ q ( p + j + γ + λ ) Γ q ( p + γ ) a p + j z p + j .

It follows from (35) that

q , p m λ + l f ( z ) z p 1 = [ p + γ ] q [ p + j + γ ] q m l Γ q ( p + j + γ ) Γ q ( p + γ + λ ) Γ q ( p + j + γ + λ ) Γ q ( p + γ ) a p + j z j < T ( γ , λ , q ) [ p + j + γ ] q [ p + γ ] q l a p + j , z E ,

where T ( γ , λ , q ) given by (31). Now, we consider the five boundary points given in Example 2. Then, we see

(36) e i β α 5 = 2 ( 3 + 2 + 3 ) 10 T ( γ , λ , q ) a p + j .

With relation given in (36), we take ρ > 1 such that

T ( γ , λ , q ) [ p + j + γ ] q [ p + γ ] q l a p + j ρ e i β α 5 .

It follows from the above that

ρ 10 2 ( 3 + 2 + 3 ) [ p + j + γ ] q [ p + γ ] q l > 1 .

Thus, we have that

q , p m λ f ( z ) z p 1 T ( γ , λ , q ) a p + j ρ [ p + γ ] q [ p + j + γ ] q l e i β α 5 < ρ e i β α 5 , z E .

Remark 7

These results correlate with uses of the q -Libera integral operator if we assume that γ = 1 in the results of this section. Let us assume that the q -Libera integral operator is written as

(37) q , p m λ f ( z ) = q , p m λ f ( z ) = z p + k = p + j [ p + 1 ] q [ k + 1 ] q m Γ q ( p + 1 + λ ) [ k ] q ! Γ q ( k + 1 + λ ) [ p ] q ! a k z k .

Taking γ = 1 in Theorems 1, 3, and 4, then we achieve the findings listed below, which are applications of the q -Libera integral operator presented in (37).

Theorem 5

If f ( z ) ( p ) satisfies

q , p m λ + 1 f ( z ) q , p m λ f ( z ) 1 < q γ e i β α s j ρ [ p + 1 ] q ( 1 + e i β α s ρ ) , z E ,

for some α s given by (19)  with α s 1 such that z l E ( l = 1 , 2 , 3 , , s ), and for some real ρ > 1 , then

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E

that is f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

Theorem 6

If f ( z ) ( p ) satisfies

( q , p m λ + l f ( z ) ) z p 1 < ρ 1 + j [ p + 1 ] q e i β α s , z E ,

for some α s given by (19) with α s 1 , ( l = 1 , 2 , 3 , , s ), and for some real ρ > 1 , then

q , p m λ + l 1 f ( z ) z p 1 < ρ e i β α s , z E .

Theorem 7

If f ( z ) ( p ) satisfies

( q , p m λ + l f ( z ) ) z p 1 < ρ 1 + j [ p + 1 ] q l e i β α s , z E ,

for some α s given by (19) with α s 1 , ( l = 1 , 2 , 3 , , s ) , and for some real ρ > 1 , then

q , p m λ f ( z ) z p 1 < ρ e i β α s , z E .

Or, equivalently, f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

3 Application of the Carathéodory lemma

This section utilizes the Carathéodory lemma to analyze the coefficients of functions f ( z ) within the class T p , j ( q , α s , β , ρ , λ , m ) .

Lemma 2

[36]. Let us have the function

g ( z ) = 1 + k = 1 c k z k

be analytic in E and Re g ( z ) > 0 , z E . Then,

(38) c k 2 , ( k 1 ) .

Inequality (38) is sharp.

We obtain the following theorem by using the aforementioned lemma.

Theorem 8

If f ( z ) ( p ) is in T p , j ( q , α s , β , ρ , λ , m ) , then

(39) a k 2 e i β α s ρ T 1 ( γ , λ , q ) , ( k = p + j , p + j + 1 , ) ,

where

(40) T 1 ( γ , λ , q ) = [ p + γ ] q [ p + γ ] q m Γ q ( k + γ ) Γ q ( p + γ + λ ) Γ q ( k + γ + λ ) Γ q ( p + γ ) .

The result is sharp for f ( z ) defined by

q , p m λ f ( z ) = z p e i θ ( 1 + 2 e i β α s ρ ) z e i θ z .

Proof

Let f ( z ) T p , j ( q , α s , β , ρ , λ , m ) , we see that

q , p m λ f ( z ) z p 1 < e i β α s ρ , z E .

If we define a function g ( z ) with f ( z ) T p , j ( q , α s , β , ρ , λ , m ) by

g ( z ) = q , p m λ f ( z ) z p ( 1 e i β α s ρ ) e i β α s ρ , z E ,

then g ( z ) is analytic in E along with Re g ( z ) > 0 , and g ( 0 ) = 1 , z E . The following power series expansion is also present for g ( z ) :

(41) g ( z ) = 1 + k = p + j T 1 ( γ , λ , q ) e i β α s ρ a k z k p .

Thus, by using Lemma 2 on (41), we obtain

T 1 ( γ , λ , q ) e i β α s ρ a k 2 ,

where

k = p + j , p + j + 1 , .

This demonstrates the coefficient inequalities (39). Consider that

g ( z ) = e i θ + z e i θ z = 1 + k = 1 2 e i θ z k = 1 + k = 1 c k z k

and g ( z ) analytic in E , along with g ( 0 ) = 1 , Re ( g ( z ) ) > 0 and c k = 2 , ( k = 1 , 2 , 3 ) . Thus, assuming f ( z ) in a way that

g ( z ) = q , p m λ f ( z ) z p ( 1 e i β α s ρ ) e i β α s ρ = e i θ + z e i θ z ,

we have

q , p m λ f ( z ) z p = ( e i θ + z ) e i β α s ρ + ( 1 e i β α s ρ ) ( e i θ z ) e i θ z q , p m λ f ( z ) = z p e i θ ( 1 + 2 e i β α s ρ ) z e i θ z .

Theorem is thus completed.□

We obtain the following result for the q -Libera integral operator by assuming that γ = 1 in Theorem 8.

Theorem 9

If f ( z ) ( p ) satisfies

q , p m λ f ( z ) z p 1 < e i β α s ρ , z E ,

then

a k 2 e i β α s ρ T 0 ( γ , λ , q ) , ( k = p + j , p + j + 1 , ) ,

where

T 0 ( γ , λ , q ) = [ p + 1 ] q [ p + 1 ] q m [ k ] q ! Γ q ( p + 1 + λ ) Γ q ( k + 1 + λ ) [ p ] q ! .

The result is sharp for f ( z ) as given by

q , p m λ f ( z ) = z p e i θ ( 1 + 2 e i β α s ρ ) z e i θ z .

Theorem 10

If f ( z ) ( p ) satisfies

(42) k = p + j T 1 ( γ , λ , q ) a k e i β α s ρ .

Then, f ( z ) T p , j ( q , α s , β , ρ , λ , m ) , where, p , j N and T 1 ( γ , λ , q ) is given by (40).

Proof

For f ( z ) ( p ) , we let

q , p m λ f ( z ) z p 1 = k = p + j T 1 ( γ , λ , q ) a k z k < k = p + j T 1 ( γ , λ , q ) a k e i β α s ρ , z E , j N .

Therefore, if f ( z ) ( p ) satisfies (42), then we know f ( z ) T p , j ( q , α s , β , ρ , λ , m ) .

Remark 8

If we take γ = 1 in Theorem 10, then we obtain result related to the q -Libera integral operator q , p m λ f ( z ) .

4 Conclusions

Currently, the application of q -calculus in GFT is a highly trending and active area of research, surpassing traditional classical techniques. While classical calculus techniques have been widely used in GFT, this article takes a novel approach by applying q -calculus techniques to explore new possibilities in the field of GFT. This article leverages the q -calculus operator theory to introduce the q -Bernardi and q -Jung-Kim-Srivastava integral operators for multivalent functions. Building on these operators, we develop a generalized fractional q -integral operator, q , p m λ f ( z ) of order λ , which encompasses various known operators for specific parameter values. The applications of these operators are investigated by defining a subclass T p , j ( q , α s , β , ρ , λ , m ) of multivalent functions via the generalized fractional q -integral operator, which enables us to study their characteristics and potential uses. Section 2 presents new results and examples for functions belonging to this new class, while Section 3 explores applications of the Carathéodory lemma, yielding additional new results.

Furthermore, this concept can be extended to meromorphic and bi-univalent functions, leveraging the operators introduced in this article. By applying these operators, we can establish numerous new subclasses of analytic and meromorphic functions, which can be explored for various useful properties, such as coefficient inequalities, Fekete-Szegő problems, partial sums, sufficient conditions, convex combinations, closure theorems, growth and distortion bounds, radii of close-to-starlikeness, and starlikeness.

Acknowledgements

The authors acknowledge Maha Alammari for her valuable input and contribution to the revised version of this manuscript.

  1. Funding information: This research did not receive external funding.

  2. Author contributions: Conceptualization, SK, AK, and IAS; data curation, SK, AS, and NMA; formal analysis, MA, SK, IAS, and WH; funding acquisition, AS; investigation, AS, AK, SK, and NMA; methodology, SK, AK, WH, and AS; project administration, AS, SK, and NMA; resources, IAS, AS, and SK; software, SK, AK, WH, and NMA; supervision, MA, SK, and IAS; validation, IAS and AS; visualization, AK and SK; writing–original draft, MA, AK, SK; writing–review and editing, SK, AS, and IAS. All authors have read and approved the final manuscript.

  3. Conflict of interest: The authors declare that they have no conflict of interest.

  4. Data availability statement: No data is used in this work.

References

[1] J. W. Alexander, Functions which map the interior of the unit circle upon simple regions, Ann. of Math. 17 (1915), 12–22. 10.2307/2007212Suche in Google Scholar

[2] A. Alb Lupas and G. I. Oros, Differential subordination and superordination results using fractional integral of confluent hypergeometric function, Symmetry 13 (2021), 327. 10.3390/sym13020327Suche in Google Scholar

[3] G. I. Oros, Study on new integral operators defined using confluent hypergeometric function, Adv. Differential Equations 2021 (2021), 342. 10.1186/s13662-021-03497-4Suche in Google Scholar

[4] H. M. Srivastava, Operators of basic (or q-) calculus and fractional q-calculus and their applications in geometric function theory of complex analysis, Iran J. Sci. Technol. A. 44 (2020), 327–344. 10.1007/s40995-019-00815-0Suche in Google Scholar

[5] H. M. Srivastava, R. Jan, A. Jan, W. Deebai, and M. Shutaywi, Fractional-calculus analysis of the transmission dynamics of the dengue infection, Chaos 31 (2021), 053130, DOI: https://doi.org/10.1063/5.0050452. 10.1063/5.0050452Suche in Google Scholar PubMed

[6] D. Baleanu, A. Jajarmi, H. Mohammadi, and S. Rezapour, A new study on the mathematical modeling of human liver with Caputo-Fabrizio fractional derivative, Chaos Solitons Fract. 134 (2020), 109705. 10.1016/j.chaos.2020.109705Suche in Google Scholar

[7] J. H. Park, H. M. Srivastava, and N. E. Cho, Univalence and convexity conditions for certain integral operators associated with the Lommel function of the first kind, AIMS Math. 6 (2021), 11380–11402. 10.3934/math.2021660Suche in Google Scholar

[8] H. Gauchman, Integral inequalities in q-calculus, Comput. Math. Appl. 47 (2004), 281–300. 10.1016/S0898-1221(04)90025-9Suche in Google Scholar

[9] Y. Tang and Z. Tie, A remark on the q-fractional order differential equations, Appl. Math. Comput 350 (2019), 198–208. 10.1016/j.amc.2019.01.008Suche in Google Scholar

[10] A. Saliu, K. Jabeen, I. Al-Shbeil, N. Aloraini, and S. N. Malik, On q-Limaçon functions, Symmetry 14 (2022), 2422. 10.3390/sym14112422Suche in Google Scholar

[11] M. F . Khan, I. Al-Shbeil, N. Aloraini, N. Khan, and S. Khan, Applications of symmetric quantum calculus to the class of harmonic functions, Symmetry 14 (2022), 2188. 10.3390/sym14102188Suche in Google Scholar

[12] F. H. Jackson, On q-definite integrals, Q. J. Pure Appl. Math. 41 (1910), 193–203. Suche in Google Scholar

[13] S. D. Purohit, A new class of multivalently analytic functions associated with fractional q-calculus operators, Fract. Differ. Calc. 2 (2012), 129–138. 10.7153/fdc-02-10Suche in Google Scholar

[14] H. M. Srivastava, Univalent functions, fractional calculus and associated generalizes hypergeometric functions, In Univalent Functions, Fractional Calculus, and Their Applications. H. M. Srivastava, S. Owa, Eds., John Wiley and Sons, New York, NY, USA; Chichester, UK; Brisbane, Australia; Toronto, ON, Canada, 1989, pp. 329–354. Suche in Google Scholar

[15] H. M. Srivastava and D. Bansal, Close-to-convexity of a certain family of q-Mittag-Leffler functions, J. Nonlinear Var. Anal. 1 (2017), 61–69. Suche in Google Scholar

[16] M. E. H. Ismail, Edward Merkes, and D. Styer, A generalization of starlike functions, Complex Variables Theory Appl. 14 (1990), 77–84. 10.1080/17476939008814407Suche in Google Scholar

[17] H. Akça, J. Benbourenane, and H. Eleuch, The q-derivative and differential equation, J. Phys. Conf. Ser. 1411 (2019), 012002. 10.1088/1742-6596/1411/1/012002Suche in Google Scholar

[18] H. Aldweby and M. Darus, A subclass of harmonic univalent functions associated with q-analogue of Dziok-Srivastava operator, ISRN Math. Anal. 2013 (2013), 382312. 10.1155/2013/382312Suche in Google Scholar

[19] H. Aldweby and M. Darus, On harmonic meromorphic functions associated with basic hypergeometric functions, Sci. World J. 2013 (2013), 164287. 10.1155/2013/164287Suche in Google Scholar PubMed PubMed Central

[20] K.A. Selvakumaran, S. D. Purohit, A. Secer, and M. Bayram, Convexity of certain q-integral operators of p-valent functions, Abstr. Appl. Anal. 2014 (2014), 925902. Suche in Google Scholar

[21] H. M. Srivastava, P. Sharma, and R. K. Raina, Inclusion results for certain classes of analytic functions associated with a new fractional differintegral operator, Rev. R. Acad. Cienc. Exactas Fís. Nat. Ser. A Mat. RACSAM 112 (2018), 271–292. 10.1007/s13398-017-0377-8Suche in Google Scholar

[22] H. M. Srivastava, M. Tahir, B. Khan, Q. Z. Ahmed, and N. Khan, Some general classes of q-starlike functions associated with the Janowski functions, Symmetry 11 (2019), 292. 10.3390/sym11020292Suche in Google Scholar

[23] P. Sharma, R. K. Raina, and J. Sokół, On a generalized convolution operator, Symmetry 13 (2021), 2141. 10.3390/sym13112141Suche in Google Scholar

[24] H. E. Ö. Uçar, Coefficient inequality for q-starlike functions, Appl. Math. Comput. 276 (2016), 122–126. 10.1016/j.amc.2015.12.008Suche in Google Scholar

[25] S. Khan, S. Hussain, and M. Darus, Certain subclasses of meromorphic multivalent q-starlike and q-convex functions, Math. Slovaca 72 (2022), 635–646. 10.1515/ms-2022-0043Suche in Google Scholar

[26] C. Zhang, S. Khan, A Hussain, N. Khan, S. Hussain, N. Khan, Applications of q-difference operator in harmonic univalent functions, AIMS Math. 7 (2021), 667–680. 10.3934/math.2022042Suche in Google Scholar

[27] H. Tang, S. Khan, S. Hussain, and N. Khan, Hankel and Toeplitz determinant for a subclass of multivalent q-starlike functions of order α, AIMS Math. 6 (2021), 5421–5439. 10.3934/math.2021320Suche in Google Scholar

[28] A. Mohammed and M. Darus, A generalized operator involving the q-hypergeometric function, Mat. Vesnik 65 (2013), 454–465. Suche in Google Scholar

[29] A. Saliu, I. Al-Shbeil, J. Gong, S. N. Malik, and N. Aloraini, Properties of q-symmetric starlike functions of Janowski type, Symmetry 14 (2022), 1907. 10.3390/sym14091907Suche in Google Scholar

[30] K. I. Noor, S. Riaz, and M. A. Noor, On q-Bernardi integral operator, TWMS J. Pure Appl. Math. 8 (2017), 3–11. 10.18576/amis/110520Suche in Google Scholar

[31] S. D. Bernardi, Convex and starlike univalent functions, Trans. Amer. Math. Soc. 135 (1969), 429–446. 10.1090/S0002-9947-1969-0232920-2Suche in Google Scholar

[32] R. J. Libera, Some classes of regular univalent functions, Proc. Amer. Math. Soc. 16 (1965), 755–758. 10.1090/S0002-9939-1965-0178131-2Suche in Google Scholar

[33] S. D. Purohit and R. K. Raina, Certain subclasses of analytic functions associated with fractional q-calculus operators, Math. Scand. 109 (2011), 55–70. 10.7146/math.scand.a-15177Suche in Google Scholar

[34] I. B. Jung, Y. C. Kim, and H. M. Srivastava, The Hardy space of analytic functions associated with certain one-parameter families of integral operators, J. Math. Anal. Appl. 176 (1993), 138–147. 10.1006/jmaa.1993.1204Suche in Google Scholar

[35] A. Çetinkaya and Y. Polatoglu, q-Harmonic mappings for which analytic part is q-convex functions of complex order, Hacet. J. Math. Stat. 47 (2018), 813–820. Suche in Google Scholar

[36] C. Carathéodory, Über den Variabilitatsbereich der Fourierschen Konstanten von positiven harmonischen Funktionen, Rend. Circ. Mat. Palermo 32 (1911), 193–217. 10.1007/BF03014795Suche in Google Scholar
Received: 2024-03-28
Revised: 2024-07-28
Accepted: 2025-04-07
Published Online: 2025-07-29

© 2025 the author(s), published by De Gruyter

This work is licensed under the Creative Commons Attribution 4.0 International License.

Artikel in diesem Heft

  1. Research Articles
  2. On approximation by Stancu variant of Bernstein-Durrmeyer-type operators in movable compact disks
  3. Circular n,m-rung orthopair fuzzy sets and their applications in multicriteria decision-making
  4. Grand Triebel-Lizorkin-Morrey spaces
  5. Coefficient estimates and Fekete-Szegö problem for some classes of univalent functions generalized to a complex order
  6. Proofs of two conjectures involving sums of normalized Narayana numbers
  7. On the Laguerre polynomial approximation errors and lower type of entire functions of irregular growth
  8. New convolutions for the Hartley integral transform imbedded in the Banach algebras and convolution-type integral equations
  9. Some inequalities for rational function with prescribed poles and restricted zeros
  10. Lucas difference sequence spaces defined by Orlicz function in 2-normed spaces
  11. Evaluating the efficacy of fuzzy Bayesian networks for financial risk assessment
  12. Fixed point results for contractions of polynomial type
  13. Estimation for spatial semi-functional partial linear regression model with missing response at random
  14. Investigating the controllability of differential systems with nonlinear fractional delays, characterized by the order 0 < η ≤ 1 < ζ ≤ 2
  15. New forms of bilateral inequalities for K-g-frames
  16. Rate of pole detection using Padé approximants to polynomial expansions
  17. Existence results for nonhomogeneous Choquard equation involving p-biharmonic operator and critical growth
  18. Note on the shape-preservation of a new class of Kantorovich-type operators via divided differences
  19. Geršhgorin-type theorems for Z1-eigenvalues of tensors with applications
  20. New topologies derived from the old one via operators
  21. Blow up solutions for two-dimensional semilinear elliptic problem of Liouville type with nonlinear gradient terms
  22. Infinitely many normalized solutions for Schrödinger equations with local sublinear nonlinearity
  23. Nonparametric expectile shortfall regression for functional data
  24. Advancing analytical solutions: Novel wave insights and methodologies for beta fractional Kuralay-II equations
  25. A generalized p-Laplacian problem with parameters
  26. A study of solutions for several classes of systems of complex nonlinear partial differential difference equations in ℂ2
  27. Towards finding equalities involving mixed products of the Moore-Penrose and group inverses by matrix rank methodology
  28. ω -biprojective and ω ¯ -contractible Banach algebras
  29. Coefficient functionals for Sakaguchi-type-Starlike functions subordinated to the three-leaf function
  30. Solutions of several general quadratic partial differential-difference equations in ℂ2
  31. Inequalities for the generalized trigonometric functions with respect to weighted power mean
  32. Optimization of Lagrange problem with higher-order differential inclusion and special boundary-value conditions
  33. Hankel determinants for q-starlike functions connected with q-sine function
  34. System of partial differential hemivariational inequalities involving nonlocal boundary conditions
  35. A new family of multivalent functions defined by certain forms of the quantum integral operator
  36. A matrix approach to compare BLUEs under a linear regression model and its two competing restricted models with applications
  37. Weighted composition operators on bicomplex Lorentz spaces with their characterization and properties
  38. Behavior of spatial curves under different transformations in Euclidean 4-space
  39. Commutators for the maximal and sharp functions with weighted Lipschitz functions on weighted Morrey spaces
  40. A new kind of Durrmeyer-Stancu-type operators
  41. A study of generalized Mittag-Leffler-type function of arbitrary order
  42. On the approximation of Kantorovich-type Szàsz-Charlier operators
  43. Split quaternion Fourier transforms for two-dimensional real invariant field
  44. Review Article
  45. Characterization generalized derivations of tensor products of nonassociative algebras
  46. Special Issue on Differential Equations and Numerical Analysis - Part II
  47. Existence and optimal control of Hilfer fractional evolution equations
  48. Persistence of a unique periodic wave train in convecting shallow water fluid
  49. Existence results for critical growth Kohn-Laplace equations with jumping nonlinearities
  50. Monotonicity and oscillation for fractional differential equations with Riemann-Liouville derivatives
  51. Nontrivial solutions for a generalized poly-Laplacian system on finite graphs
  52. Stability and bifurcation analysis of a modified chemostat model
  53. Special Issue on Nonlinear Evolution Equations and Their Applications - Part II
  54. Analytic solutions of a generalized complex multi-dimensional system with fractional order
  55. Extraction of soliton solutions and Painlevé test for fractional Peyrard-Bishop DNA model
  56. Special Issue on Recent Developments in Fixed-Point Theory and Applications - Part II
  57. Some fixed point results with the vector degree of nondensifiability in generalized Banach spaces and application on coupled Caputo fractional delay differential equations
  58. On the sum form functional equation related to diversity index
  59. Special Issue on International E-Conference on Mathematical and Statistical Sciences - Part II
  60. Simpson, midpoint, and trapezoid-type inequalities for multiplicatively s-convex functions
  61. Converses of nabla Pachpatte-type dynamic inequalities on arbitrary time scales
  62. Special Issue on Blow-up Phenomena in Nonlinear Equations of Mathematical Physics - Part II
  63. Energy decay of a coupled system involving a biharmonic Schrödinger equation with an internal fractional damping
  64. Special Issue on Some Integral Inequalities, Integral Equations, and Applications - Part II
  65. Nonlinear heat equation with viscoelastic term: Global existence and blowup in finite time
  66. New Jensen's bounds for HA-convex mappings with applications to Shannon entropy
  67. Special Issue on Approximation Theory and Special Functions 2024 conference
  68. Ulam-type stability for Caputo-type fractional delay differential equations
  69. Faster approximation to multivariate functions by combined Bernstein-Taylor operators
  70. (λ, ψ)-Bernstein-Kantorovich operators
  71. Some special functions and cylindrical diffusion equation on α-time scale
  72. (q, p)-Mixing Bloch maps
  73. Orthogonalizing q-Bernoulli polynomials
  74. On better approximation order for the max-product Meyer-König and Zeller operator
  75. Moment-based approximation for a renewal reward process with generalized gamma-distributed interference of chance
  76. A note on linear compositions of the Mellin convolution operators in the weighted Mellin-Lebesgue spaces
  77. A new perspective on generalized Laguerre polynomials
  78. Global existence of semilinear system of Klein-Gordon equations in anti-de Sitter spacetime
  79. Estimates for Durrmeyer-type exponential sampling series in Mellin-Orlicz spaces
  80. Special Issue on Variational Methods and Nonlinear PDEs
  81. A note on mean field type equations
  82. Ground states for fractional Kirchhoff double-phase problem with logarithmic nonlinearity
  83. Solution of nonlinear Langevin equations involving Hilfer-Hadamard fractional order derivatives and variable coefficients
https://doi.org/10.1515/dema-2025-0128
Schlagwörter für diesen Artikel
analytic functions; q-Bernardi integral operator; multivalent analytic functions; q-difference operator; fractional q-integral operator; q-Jack’s lemma
Creative Commons
BY 4.0

Artikel in diesem Heft

  1. Research Articles
  2. On approximation by Stancu variant of Bernstein-Durrmeyer-type operators in movable compact disks
  3. Circular n,m-rung orthopair fuzzy sets and their applications in multicriteria decision-making
  4. Grand Triebel-Lizorkin-Morrey spaces
  5. Coefficient estimates and Fekete-Szegö problem for some classes of univalent functions generalized to a complex order
  6. Proofs of two conjectures involving sums of normalized Narayana numbers
  7. On the Laguerre polynomial approximation errors and lower type of entire functions of irregular growth
  8. New convolutions for the Hartley integral transform imbedded in the Banach algebras and convolution-type integral equations
  9. Some inequalities for rational function with prescribed poles and restricted zeros
  10. Lucas difference sequence spaces defined by Orlicz function in 2-normed spaces
  11. Evaluating the efficacy of fuzzy Bayesian networks for financial risk assessment
  12. Fixed point results for contractions of polynomial type
  13. Estimation for spatial semi-functional partial linear regression model with missing response at random
  14. Investigating the controllability of differential systems with nonlinear fractional delays, characterized by the order 0 < η ≤ 1 < ζ ≤ 2
  15. New forms of bilateral inequalities for K-g-frames
  16. Rate of pole detection using Padé approximants to polynomial expansions
  17. Existence results for nonhomogeneous Choquard equation involving p-biharmonic operator and critical growth
  18. Note on the shape-preservation of a new class of Kantorovich-type operators via divided differences
  19. Geršhgorin-type theorems for Z1-eigenvalues of tensors with applications
  20. New topologies derived from the old one via operators
  21. Blow up solutions for two-dimensional semilinear elliptic problem of Liouville type with nonlinear gradient terms
  22. Infinitely many normalized solutions for Schrödinger equations with local sublinear nonlinearity
  23. Nonparametric expectile shortfall regression for functional data
  24. Advancing analytical solutions: Novel wave insights and methodologies for beta fractional Kuralay-II equations
  25. A generalized p-Laplacian problem with parameters
  26. A study of solutions for several classes of systems of complex nonlinear partial differential difference equations in ℂ2
  27. Towards finding equalities involving mixed products of the Moore-Penrose and group inverses by matrix rank methodology
  28. ω -biprojective and ω ¯ -contractible Banach algebras
  29. Coefficient functionals for Sakaguchi-type-Starlike functions subordinated to the three-leaf function
  30. Solutions of several general quadratic partial differential-difference equations in ℂ2
  31. Inequalities for the generalized trigonometric functions with respect to weighted power mean
  32. Optimization of Lagrange problem with higher-order differential inclusion and special boundary-value conditions
  33. Hankel determinants for q-starlike functions connected with q-sine function
  34. System of partial differential hemivariational inequalities involving nonlocal boundary conditions
  35. A new family of multivalent functions defined by certain forms of the quantum integral operator
  36. A matrix approach to compare BLUEs under a linear regression model and its two competing restricted models with applications
  37. Weighted composition operators on bicomplex Lorentz spaces with their characterization and properties
  38. Behavior of spatial curves under different transformations in Euclidean 4-space
  39. Commutators for the maximal and sharp functions with weighted Lipschitz functions on weighted Morrey spaces
  40. A new kind of Durrmeyer-Stancu-type operators
  41. A study of generalized Mittag-Leffler-type function of arbitrary order
  42. On the approximation of Kantorovich-type Szàsz-Charlier operators
  43. Split quaternion Fourier transforms for two-dimensional real invariant field
  44. Review Article
  45. Characterization generalized derivations of tensor products of nonassociative algebras
  46. Special Issue on Differential Equations and Numerical Analysis - Part II
  47. Existence and optimal control of Hilfer fractional evolution equations
  48. Persistence of a unique periodic wave train in convecting shallow water fluid
  49. Existence results for critical growth Kohn-Laplace equations with jumping nonlinearities
  50. Monotonicity and oscillation for fractional differential equations with Riemann-Liouville derivatives
  51. Nontrivial solutions for a generalized poly-Laplacian system on finite graphs
  52. Stability and bifurcation analysis of a modified chemostat model
  53. Special Issue on Nonlinear Evolution Equations and Their Applications - Part II
  54. Analytic solutions of a generalized complex multi-dimensional system with fractional order
  55. Extraction of soliton solutions and Painlevé test for fractional Peyrard-Bishop DNA model
  56. Special Issue on Recent Developments in Fixed-Point Theory and Applications - Part II
  57. Some fixed point results with the vector degree of nondensifiability in generalized Banach spaces and application on coupled Caputo fractional delay differential equations
  58. On the sum form functional equation related to diversity index
  59. Special Issue on International E-Conference on Mathematical and Statistical Sciences - Part II
  60. Simpson, midpoint, and trapezoid-type inequalities for multiplicatively s-convex functions
  61. Converses of nabla Pachpatte-type dynamic inequalities on arbitrary time scales
  62. Special Issue on Blow-up Phenomena in Nonlinear Equations of Mathematical Physics - Part II
  63. Energy decay of a coupled system involving a biharmonic Schrödinger equation with an internal fractional damping
  64. Special Issue on Some Integral Inequalities, Integral Equations, and Applications - Part II
  65. Nonlinear heat equation with viscoelastic term: Global existence and blowup in finite time
  66. New Jensen's bounds for HA-convex mappings with applications to Shannon entropy
  67. Special Issue on Approximation Theory and Special Functions 2024 conference
  68. Ulam-type stability for Caputo-type fractional delay differential equations
  69. Faster approximation to multivariate functions by combined Bernstein-Taylor operators
  70. (λ, ψ)-Bernstein-Kantorovich operators
  71. Some special functions and cylindrical diffusion equation on α-time scale
  72. (q, p)-Mixing Bloch maps
  73. Orthogonalizing q-Bernoulli polynomials
  74. On better approximation order for the max-product Meyer-König and Zeller operator
  75. Moment-based approximation for a renewal reward process with generalized gamma-distributed interference of chance
  76. A note on linear compositions of the Mellin convolution operators in the weighted Mellin-Lebesgue spaces
  77. A new perspective on generalized Laguerre polynomials
  78. Global existence of semilinear system of Klein-Gordon equations in anti-de Sitter spacetime
  79. Estimates for Durrmeyer-type exponential sampling series in Mellin-Orlicz spaces
  80. Special Issue on Variational Methods and Nonlinear PDEs
  81. A note on mean field type equations
  82. Ground states for fractional Kirchhoff double-phase problem with logarithmic nonlinearity
  83. Solution of nonlinear Langevin equations involving Hilfer-Hadamard fractional order derivatives and variable coefficients
Jetzt anmelden und 20% sparen
Institutioneller Zugang
Wie funktioniert Authentifizierung?
Haben Sie eine Idee, wie wir unsere Website verbessern können?
Bitte schreiben Sie uns.
© 2025 De Gruyter Brill
Heruntergeladen am 22.9.2025 von https://www.degruyterbrill.com/document/doi/10.1515/dema-2025-0128/html
Button zum nach oben scrollen