1. Introduction
In many branches of mathematics and physics, an important role is played by the theory of
q-analysis. We can mention here several areas, such as ordinary fractional calculus, problems of optimal control,
q-integral equations,
q-difference and
q-transform analysis (for example, see [
1,
2,
3,
4]). The study of
q-calculus has experienced accelerated development, especially after the pioneering work of M. E. H. Ismail et al. [
5]. This was followed by similar works, such as those of S. Kanas and D. Raducanu [
6] and S. Sivasubramanian and M. Govindaraj [
7]. In the beginning, we will describe some special concepts of
q-calculus. Consider the class of meromorphic functions denoted by
on the form:
They are analytic in
, the open punctured unit disc:
We say that
is a meromorphic starlike function of order
if the following inequality is satisfied:
Let us denote by
such a class of functions. Pommerenke [
8] introduced and studied the class
(see also Miller [
9]).
Consider the class of meromorphic functions denoted by
having the property
The function
is an analytic function such that
,
and
. The domain
U is mapped onto a region that is starlike with respect to 1 and is a symmetric region with respect to the real axis. Silverman et al. [
10] introduced and studied the class
. When the function
has the special form
, then the class
is the particular case of the class
.
The notion of
q-derivative
is defined by Gasper and Rahman [
2] as
From definition (
2), we find that
is given by
for a function
f of the form (
1). When
, then
and we deduce
2. Basic Results and Definitions
In the present section, we recall a few well-known statements and related elements in post-quantum calculus. Given the new results in the previous section, we need the required elements of the
-calculus. Lately, there have been many authors concerned with
-calculus. We recall here [
11,
12]. The post-quantum calculus denoted by the
-calculus is an extension of the
q-calculus (see [
13,
14]).
The theory of post-quantum calculus ([
15]) operators is useful in the theory of geometric function and also in many areas of science. The
-number is given by
which is a natural extension of the
q-number: we have ([
16,
17]). Moreover, the
Additionally, the
-factorial is
The
-Gamma function, for a complex number
x, is defined by
where
Remark 1. The function q-Gamma, denoted by , is a special case of -Gamma function if .
Our present paper is based on geometric function theory and implies a given application in the open unit disk. We formulate two analytic function classes depending on the symmetry properties. Using a symmetric operator, we deduce many interesting properties.
Lemma 1 ([
18]).
Consider the function p such that in U and Then,where μ is a complex number. This is a sharp result for the functions given by Lemma 2 ([
18]).
Consider the function such that in U and . Then,When or , the equality holds if and only if or one of its rotations. If 0 , then the equality holds if and only if or one of its rotations. If the equality holds if and only if or one of its rotations. If , the equality holds if and only if or one of its rotations. Moreover, the above upper bounds are sharp and can be improved as follows when 0 Next, with the extended idea of the q-difference operator, we have:
Definition 1 ([
12]).
Let and . Then, the -derivative operator or -difference operator for the function f of the form (1) is defined by We observe that if
,
and we reobtain the operator from (
2).
As
and we have
The findings and properties proven in this work are a natural extension of those analogous in q-calculus theory and also contribute to the theory of inequalities. In this manner, the famous problem of Fekete–Szegö for meromorphic functions starts to develop within the topic of -calculus. Many of the newly established inequalities are natural extensions of some already given inequalities. In the final part of this paper, interesting applications of the new results are considered. A new -analogue of the q-Wright type hypergeometric function is introduced and some relations among properties and inequalities are developed.
3. Fekete–Szegö Problem for Meromorphic
Functions in the Post-Quantum Calculus Case
Using the -derivative operator, we define the following classes:
Definition 2. For , a function is said to be in the class if and only if Special cases of this class were studied by different authors as follows:
- (i)
(see Bulboacă [
19]);
- (ii)
(see Aouf [
20]);
- (iii)
(see El-Ashwah and Aouf [
21]);
- (iv)
with
(see [
22], for
).
Definition 3. For a function is said to be in the class if and only if We recall here some special classes studied earlier by various authors.
- (i)
(see Aouf et al. [
23]);
- (ii)
(see Pommerenke [
8]);
- (iii)
(see Kulkarni and Joshi [
24]);
- (iv)
, (see Karunakaran [
25]).
In 2001, Virchenko et al. (see [
26]) studied and investigated a Wright type hypergeometric function. For another special case, see [
27]. In order to consider the application in the last section, we propose a new form of this function in terms of
-calculus.
Definition 4. For the -Wright type hypergeometric function is defined by Remark 2. The above-defined function is an extension of the classical Gauss hypergeometric function denoted by
We now deduce an important result of this paper.
Theorem 1. Consider the function If the function f is in the form (1) and belonging to the class , then where μ is a complex number. The result is sharp.
Proof. Let
Then, there exists
a Schwarz function such that
and
in
U with
We note that and since is a Schwarz function.
Taking into account the relations (
10)–(
12), we obtain
Using the above relation and (
12), we deduce
and
Thus, from (
1) and (
12), we see that
and
or, equivalently, we obtain
and
Therefore, after computation,
where
Thus, the result (
8) is deduced by an application of Lemma 1. If
, then
If
, then
(see Nehari [
28]). Hence,
proving (
9). For the following functions, the result is sharp.
and
Thus, the proof of Theorem 1 is complete. □
Putting , one obtains the next corollary.
Corollary 1. Consider f in the form (1) belonging to the class . Then, where μ is a complex number. The result is sharp.
The following theorem is obtained by using Lemma 2.
Theorem 2. Consider the functionIf the function f in the form (1) belonging to the classthenwhere The result is sharp. Further, let
Proof. First, let
then
Consider
Then, we obtain
We define the function
in order to show that the bounds are sharp
We have also the functions
and
given by
and
Obviously, , and . When or , then we consider the equality if and only if f is or one of its rotations. If , then we consider the equality if f is or one of its rotations. When we consider then the equality takes place if and only if f is or one of its rotations. If then the equality holds if and only if f is or one of its rotations. Thus, we complete the proof of Theorem 2. □
Remark 3. - (i)
Forin Theorem 2, we deduce the result obtained by Huo Tang et al. [29]; - (ii)
Puttingandin Theorem 2, we have a new result for the class
Theorem 3. ConsiderIf the function f in the form (1) belonging to the subclassand μ is a complex number, then The result is sharp.
Proof. If
f belongs to the subclass
then there exists
w a Schwarz function in
U such that
and
with
Let
be the function
We observe that and , since w is a Schwarz function.
Now, we define the function
Taking into account the relations (
24)–(
26), we obtain
Using the above relation and (
27), we deduce
and
Thus, from (
1) and (
26), we see that
and
or, equivalently, we obtain
and
Therefore, after computation,
where
Thus, the result (
22) is obtained by applying Lemma 1. If
, then
Since
, then
(see Nehari [
28]). Hence,
proving (
23). The result is sharp for the functions
and
Thus, we complete Theorem 3. □
Letting , we derive the following corollary.
Corollary 2. Consider f in the form (1) and belonging to the subclass and μ is a complex number, then The result is sharp.
Applying Lemma 2, we deduce the following theorem.
Theorem 4. Consider the function with If the function f is in the form (1) and belongs to the subclass then The result is sharp. Further, let
Proof. First, let
then
Consider
Then, we have
Finally, if
then
We define the function
in order to show that the bounds are sharp
and
and
by
and
Obviously, , and When or , consider the equality if and only if f is or one of its rotations. If , then consider the equality if f is or one of its rotations. When then the equality holds if and only if f is or one of its rotations. When then the equality holds if and only if f is or one of its rotations. Thus, we complete the proof of Theorem 4. □
Remark 4. - (i)
For in Theorem 4, we reobtain a result from [23]; - (ii)
Putting and in Theorem 4, we obtain the result deduced by Ali and Ravichandran [30].
4. Applications to Functions Defined by the -Wright Type Hypergeometric Function
Considering the
-Wright type hypergeometric function given in definition 4, let us define
We define the linear operator denoted by
by using the Hadamard product,
, as follows:
Further, we define two classes by using the operator defined in (
37).
With
and
, let us consider
and
two subclasses of
consisting of functions
f in the form (
1) and satisfying the analytic criteria, respectively:
and
Using similar arguments to those in the proof of the above theorems, we obtain the following results related to the classes.
Theorem 5. Consider If the function f in the form (1) belonging to the subclass and μ is a complex number, then The result is sharp.
Theorem 6. Consider the function If the function f given by (1) belonging to the subclass then The result is sharp. Further, let
Theorem 7. Consider If given by the form (1) belongs to the class , , , , and μ is a complex number, then The result is sharp.
Theorem 8. Let the function , , , , and If given by (1) belongs to the class then The result is sharp. Further, let
5. Conclusions
In the present paper, with the extended idea of a symmetric -difference operator, we have introduced two subclasses of meromorphic functions. For certain values of the parameters, we reobtain some special classes studied earlier by various authors. The new results estimate the upper bound coefficients expressed in the Fekete–Szegö problem. We also deduce results that generalize and improve several previously known ones. In addition, we also provide certain applications to support our obtained results. Thus, an interesting aspect of the paper consists in defining the -Wright type hypergeometric function, which is used as an application of the new form of this function in terms of -calculus. We still intend to continue the work on the present issue. In this direction, for future research:
- (i)
we intend to investigate new symmetric -differential operators;
- (ii)
similar results for other special classes of meromorphic functions are anticipated;
- (iii)
new aspects of the Fekete–Szegö problem for meromorphic functions are targeted;
- (iv)
the relationship between the results provided here and comparable outcomes in the field can be also considered.
The results of this study can be applied to post-quantum theory and symmetry. We hope that the new ideas and the new techniques given in the present paper will attract interested readers in the field of geometric function theory.