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Article

Symmetric Conformable Fractional Derivative of Complex Variables

by
Rabha W. Ibrahim
1,2,
Rafida M. Elobaid
3,* and
Suzan J. Obaiys
4
1
Informetrics Research Group, Ton Duc Thang University, Ho Chi Minh City 758307, Vietnam
2
Faculty of Mathematics & Statistics, Ton Duc Thang University, Ho Chi Minh City 758307, Vietnam
3
Department of General Sciences, Prince Sultan University, Riyadh 12435, Saudi Arabia
4
School of Mathematical and Computer Sciences, Heriot-Watt University, Putrajaya 62200, Malaysia
*
Author to whom correspondence should be addressed.
Mathematics 2020, 8(3), 363; https://doi.org/10.3390/math8030363
Submission received: 19 February 2020 / Revised: 2 March 2020 / Accepted: 3 March 2020 / Published: 6 March 2020
(This article belongs to the Special Issue Geometrical Theory of Analytic Functions)

Abstract

:
It is well known that the conformable and the symmetric differential operators have formulas in terms of the first derivative. In this document, we combine the two definitions to get the symmetric conformable derivative operator (SCDO). The purpose of this effort is to provide a study of SCDO connected with the geometric function theory. These differential operators indicate a generalization of well known differential operator including the Sàlàgean differential operator. Our contribution is to impose two classes of symmetric differential operators in the open unit disk and to describe the further development of these operators by introducing convex linear symmetric operators. In addition, by acting these SCDOs on the class of univalent functions, we display a set of sub-classes of analytic functions having geometric representation, such as starlikeness and convexity properties. Investigations in this direction lead to some applications in the univalent function theory of well known formulas, by defining and studying some sub-classes of analytic functions type Janowski function and convolution structures. Moreover, by using the SCDO, we introduce a generalized class of Briot–Bouquet differential equations to introduce, what is called the symmetric conformable Briot–Bouquet differential equations. We shall show that the upper bound of this class is symmetric in the open unit disk.

1. Introduction

The term Symmetry from Greek means arrangement and organization in measurements. In free language, it mentions a concept of harmonious and attractive proportion and equilibrium. In mathematics, it discusses an object that is invariant via certain transformation or rotation or scaling. In geometry, the object has symmetry if there is an operator or transformation that maps the object onto itself [1,2].
Sàlàgean (1983) presented a differential operator for a class of analytic functions (see [3]). Many sub-classes of analytic functions are studied using this operator. Al-Oboudi [4] generalized this operator. These operators are studied widely in the last decade (see [5,6,7,8,9,10] for recent works). Our investigation is to study classes of analytic functions by using the symmetric differential operator in a complex domain. Recently, Ibrahim and Jahangiri [7] defined a special type of differential operators, which is called a complex conformable differential operator. This operator is an extension of the Anderson–Ulness operator [11].
A conformable calculus (CC) is a branch of the fractional calculus. It develops the term χ 1 f ( χ ) . While the complex conformable calculus (CCC) indicates the term ξ φ ( ξ ) , where ξ is a complex variable and φ is a complex valued analytic function. In this work, we present a new SCDO in the open unit disk. We formulate it in some sub-classes of univalent functions. As applications, we generalize a class of Briot–Bouquet differential equations by using SCDO.

2. Methodology

This section deals with the mathematical processing to study the SCDO for some classes of analytic functions in the open unit disk = { ξ C : | ξ | < 1 } . Let ⋀ be the following class of analytic functions
( ξ ) = ξ + n = 2 n ξ n , ξ .
A function is starlike via the (0,0) ( origin in ∪) if the linear segment joining the origin to every other point of ⋎ lies entirely in ( ξ : | ξ | < 1 ) . A univalent function ( ) is convex in ∪ if the linear segment joining any two points of ( ξ : | ξ | < 1 ) lies entirely in ( ξ : | ξ | < 1 ) . We denote these classes by S * and C for starlike and convex respectively. In addition, suppose that the class P involves all functions ⋎ analytic in ∪ with a positive real part in ∪ achieving ( 0 ) = 1 . Mathematically, S * if and only if ξ ( ξ ) / ( ξ ) P and C if and only if 1 + ξ ( ξ ) / ( ξ ) P . Equivalently, ( ξ ( ξ ) / ( ξ ) ) > 0 for the starlikeness and 1 + ( ξ ( ξ ) / ( ξ ) ) > 0 for the convexity.
For two functions 1 and 2 belong to the class , are said to be subordinate, noting by 1 2 , if we can find a Schwarz function ⊺ with ( 0 ) = 0 and | ( ξ ) | < 1 achieving 1 ( ξ ) = 2 ( ( ξ ) ) , ξ (the detail can be located in [12]). Obviously, 1 ( ξ ) 2 ( ξ ) if 1 ( 0 ) = 2 ( 0 ) and 1 ( ) 2 ( ) .
Lemma 1
([12]). Suppose that a C , n is a positive integer and [ a , n ] = { : ( ξ ) = a + a n ξ n + a n + 1 ξ n + 1 + } is a set of analytic functions.
i. If R then ( ξ ) + ξ ( ξ ) > 0 ( ξ ) > 0 . In addition, if > 0 and [ 1 , n ] , then there occurs some constants a > 0 and b > 0 with b = b ( , a , n ) where
( ξ ) + ξ ( ξ ) 1 + ξ 1 ξ b ( ξ ) 1 + ξ 1 ξ a .
ii. If ð [ 0 , 1 ) and [ 1 , n ] then a constant k > 0 exists satisfying k = k ( a , n ) so that
2 ( ξ ) + 2 ( ξ ) · ξ ( ξ ) > ð ( ( ξ ) ) > k .
iii. If [ a , n ] with ( a ) > 0 then ( ξ ) + ξ ( ξ ) + ξ 2 ( ξ ) > 0 or for ɩ : R with ( ξ ) + ɩ ( ξ ) ξ ( ξ ) ( ξ ) > 0 then ( ( ξ ) ) > 0 .
Lemma 2
([12]). Assume that ℏ is a convex function satisfying ( 0 ) = a , and let k C   \   { 0 } be a complex number with ( k ) 0 . If [ a , n ] , and
( ξ ) + ( 1 / k ) ξ ( ξ ) ( ξ ) , ξ ,
then ( ξ ) ι ( z ) ( z ) , where
ι ( z ) = k n ξ k / n 0 ξ ( τ ) τ k ( n 1 ) d τ , ξ .
Lemma 3
([13]). Suppose that and there occurs a positive constant 0 < υ 1 . If
ξ ( ξ ) ξ ( ξ ) 2 υ ξ 1 + ξ
then
( ξ ) ξ 1 + υ ξ , ξ .
And the result is sharp.

The Operator SCDO

This sections deals with definition of the SCDO as follows:
Definition 1. 
Let ( ξ ) , and let ν [ 0 , 1 ] be a constant then the SCDO keeps the following operating
S ν 0 ( ξ ) = ( ξ ) S ν 1 ( ξ ) = κ 1 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) ξ ( ξ ) κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) ξ ( ξ ) = κ 1 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) ξ + n = 2 n n ξ n κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) ξ + n = 2 n ( 1 ) n n ξ n = ξ + n = 2 n κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) n ξ n S ν 2 ( ξ ) = S ν 1 [ S ν 1 ( ξ ) ] = ξ + n = 2 n 2 κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) 2 n ξ n S ν k ( ξ ) = S ν 1 [ S ν k 1 ( ξ ) ] = ξ + n = 2 n k κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) k n ξ n .
so that κ 1 ( ν , ξ ) κ 0 ( ν , ξ ) ,
lim ν 0 κ 1 ( ν , ξ ) = 1 , lim ν 1 κ 1 ( ν , ξ ) = 0 , κ 1 ( ν , ξ ) 0 , ξ , ν ( 0 , 1 ) ,
and
lim ν 0 κ 0 ( ν , ξ ) = 0 , lim ν 1 κ 0 ( ν , ξ ) = 1 , κ 0 ( ν , ξ ) 0 , ξ ν ( 0 , 1 ) .
The value ν = 0 indicates the Sàlàgean operator S k ( ξ ) = ξ + n = 2 n k n ξ n . We proceed to impose a linear differential operator having the SCDO and the Ruscheweyh derivative. For , the Ruscheweyh derivative is defined as follows:
R k ( ξ ) = ξ + n = 2 k + n 1 k n ξ n ,
where k + n 1 k are the combination terms.
Definition 2. 
Let , ν [ 0 , 1 ] and 0 α 1 . The linear combination operator joining R k ( ξ ) and S ν k ( ξ ) is given by the formal
C ν , α k ( ξ ) = ( 1 α ) R k ( ξ ) + α S ν k ( ξ ) = ξ + n = 2 ( 1 α ) k + n 1 k + α n κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) k n ξ n .
Remark 1. 
  • k = 0 C ν , α 0 ( ξ ) = ( ξ ) ;
  • ν = 0 C 1 , α k ( ξ ) = L κ k ( ξ ) ; [14] (Lupas operator)
  • α = 0 C ν , α k ( ξ ) = R k ( ξ ) ;
  • α = 1 , κ = 1 C 0 , 1 k ( ξ ) = S k ( ξ ) ;
  • α = 1 C ν , 1 k ( ξ ) = S ν k ( ξ ) .
Definition 3. 
Let ϵ [ 0 , 1 ) , ν , α [ 0 , 1 and k N . A function belongs to the set B k ( ν , α , ϵ ) if and only if
( C ν , α k ( ξ ) ) > ϵ , ξ .
Definition 4. 
The function is specified to be in J ν ( A , B , k ) if it satisfies the inequality
1 + 1 2 S ν k + 1 ( ξ ) S ν k ( ξ ) S ν k ( ξ ) 1 + A ξ 1 + B ξ ,
ξ , 1 B < A 1 , k = 1 , 2 , , C { 0 } , ν [ 0 , 1 ] .
  • ν = 0 [6];
  • ν = 0 , B = 0 [7];
  • ν = 0 , A = 1 , B = 1 , = 2 [8].
The class J ν ( A , B , k ) is a generalization of the class of the Janowski starlike functions [15]
ρ ( ξ ) 1 + A ξ 1 + B ξ , ξ ,
where ρ ( 0 ) = 1 , ρ ( ) Ω [ A , B ] . The domain Ω [ A , B ] is a circular domain and it is referring to an open circular disk with center on the real axis and diameter end points 1 A 1 B , provide that B 1 . Functions in the class J ν ( A , B , k ) have a circular domain with respect to symmetrical points.
Definition 5. 
Let ϵ [ 0 , 1 ) , ν , α [ 0 , 1 and k N 0 . A function is in the set S k ( ν , ϵ ) if it achieves the real inequality
S ν k + 1 ( ξ ) S ν k ( ξ ) > ϵ , ξ .
Note that S 0 ( ν , ϵ ) = S * , S 1 ( 0 , ϵ ) = C

3. The Outcomes

In this section, we study some properties of the SCDO.
Theorem 1. 
For and α C { 0 } , if one of the sequencing subordination valid
  • The operator S ν k ( ξ ) is of bounded turning type;
  • satisfies the relation
    ( S ν k ( ξ ) ) 1 + ξ 1 ξ b , b > 0 , ξ ;
  • fulfilled the inequality
    ( S ν k ( ξ ) ) S ν k ( ξ ) ξ > δ 2 , δ [ 0 , 1 ) , ξ ,
  • admits the inequality
    ξ S ν k ( ξ ) ) S ν k ( ξ ) ) + 2 S ν k ( ξ ) ) ξ > 0 ,
  • confesses the inequality
    ξ S ν k ( ξ ) ) S ν k ( ξ ) ) + 2 S ν k ( ξ ) ξ > 1 ,
then S ν k ( ξ ) ξ P ( ϵ ) , ϵ [ 0 , 1 ) .
Proof. 
Formulate a function σ as pursues:
σ ( ξ ) = S ν k ( ξ ) ξ ξ σ ( ξ ) + σ ( ξ ) = ( S ν k ( ξ ) ) .
By the first relation, S ν k ( ξ ) is of bounded turning, this indicates that
( ξ σ ( ξ ) + σ ( ξ ) ) > 0 .
Therefore, according to Lemma 1—i, we attain ( σ ( ξ ) ) > 0 which gets the first term of the theorem. According to second inequality, we indicate the pursuing subordination inequality
( S ν k ( ξ ) ) = ξ σ ( ξ ) + σ ( ξ ) 1 + ξ 1 ξ b .
Now, by employing Lemma 1—i, there occurs a fixed constant a > 0 with b = b ( a ) with the pursuing property
S ν k ( ξ ) ξ 1 + ξ 1 ξ a .
Consequently, we indicate that ( S ν k ( ξ ) / ξ ) > ϵ , for values of ϵ [ 0 , 1 ) . Lastly, agree with the third relation to get
σ 2 ( ξ ) + 2 σ ( ξ ) · ξ σ ( ξ ) = 2 ( S ν k ( ξ ) ) S ν k ( ξ ) ξ > δ .
According to Lemma 1—ii, there occurs a positive fixed number λ > 0 achieving the real inequality ( σ ( ξ ) ) > λ , and yielding
σ ( ξ ) = S ν k ( ξ ) ξ P ( ϵ )
for a few value in ϵ [ 0 , 1 ) . It indicates from (5) that S ν k ( ξ ) ) > 0 ; thus, according to Noshiro-Warschawski and Kaplan Lemmas, this leads to S ν k ( ξ ) is univalent and of bounded turning in ∪. Now, via the differentiating (4) and concluding the real case, we indicate that
σ ( ξ ) + ξ σ ( ξ ) + ξ 2 σ ( ξ ) = ξ ( S ν k ( ξ ) ) ( S ν k ( ξ ) ) + 2 S ν k ( ξ ) ξ > 0 .
Thus, by the conclusion of Lemma 1—ii, we have
( S ν k ( ξ ) ξ ) > 0 .
Taking the logarithmic differentiation (4) and indicating the real, we arrive at the following conclusion:
σ ( ξ ) + ξ σ ( ξ ) σ ( ξ ) + ξ 2 σ ( ξ ) = ξ ( S ν k ( ξ ) ) S ν k ( ξ ) + 2 Δ α m ( ξ ) ξ 1 > 0 .
A direct application of Lemma 1—iii, we get the positive real i.e., ( S ν k ( ξ ) ξ ) > 0 . This completes the proof. □
Theorem 2. 
Suppose that J α ( A , B , m ) then for every function of the form
X ( ξ ) = 1 2 [ ( ξ ) ( ξ ) ] , ξ
agrees with the pursuing relation
1 + 1 S ν k + 1 X ( ξ ) S ν k X ( ξ ) 1 1 + A ξ 1 + B ξ ,
and
ξ X ( ξ ) X ( ξ ) 1 2 1 + 2 , | ξ | = < 1 ,
ξ , 1 B < A 1 , m = 1 , 2 , , C { 0 } , ν [ 0 , 1 ] .
Proof. 
Because the function J α ( A , B , m ) then there occurs a function J ( A , B ) , where
( ( ξ ) 1 ) = 2 S ν k + 1 ( ξ ) S ν k ( ξ ) S ν k ( ξ )
and
( ( ξ ) 1 ) = 2 S ν k + 1 ( ξ ) S ν k ( ξ ) S ν k ( ξ ) .
This implies that
1 + 1 S ν k + 1 X ( ξ ) S ν k X ( ξ ) 1 = ( ξ ) + ( ξ ) 2 .
Also, since ( ξ ) 1 + ξ 1 + ξ , where 1 + ξ 1 + ξ is univalent then by the concept of the subordination, we have
1 + 1 S ν k + 1 X ( ξ ) Δ α m X ( ξ ) 1 1 + A ξ 1 + B ξ .
But the function X ( ξ ) is starlike in , which means that
ξ X ( ξ ) X ( ξ ) 1 ξ 2 1 + ξ 2
and there occurs a Schwarz function , | ( ξ ) | | ξ | < 1 , ( 0 ) = 0 such that
Ψ ( ξ ) : = ξ X ( ξ ) X ( ξ ) 1 ( ξ ) 2 1 + ( ξ ) 2 .
This implies that there exists ζ , | ζ | = < 1 achieving
2 ( ζ ) = 1 Ψ ( ζ ) 1 + Ψ ( ζ ) , ζ .
A computation yields
| 1 Ψ ( ζ ) 1 + Ψ ( ζ ) | = | ( ζ ) | 2 | ζ | 2 .
Thus, we conclude that
| Ψ ( ζ ) 1 + | ζ | 4 1 | ζ | 4 | 2 4 | ζ | 4 ( 1 | ζ | 4 ) 2
or
| Ψ ( ζ ) 1 + | ζ | 4 1 | ζ | 4 | 2 | ζ | 2 ( 1 | ζ | 4 ) .
Consequently, we obtain
( Ψ ( ζ ) ) 1 2 1 + 2 , | ζ | = < 1 .
 □
Theorem 3. 
Suppose that B k ( ν , α , ϵ ) , and the convex analytic function g satisfies the integral equation
F ( ξ ) = 2 + c ξ 1 + c 0 ξ τ c ( τ ) d τ , ξ
then the subordination
C ν , α k ( ξ ) g ( ξ ) + ( ξ g ( ξ ) ) 2 + c , c > 0 ,
implies the subordination
C ν , α k F ( ξ ) g ( ξ ) ,
and the outcome is sharp.
Proof. 
Here, we aim to utilize the result of Lemma 2. By the conclusion of F ( ξ ) , we acquire
C ν , α k F ( ξ ) + C ν , α k F ( ξ ) 2 + c = C ν , α k ( ξ ) .
Following the conditions of the theorem, we get
C ν , α k F ( ξ ) + C ν , α k F ( ξ ) 2 + c g ( ξ ) + ( ξ g ( ξ ) ) 2 + c .
By assuming
ϱ ( ξ ) : = C ν , α k F ( ξ ) ,
We have
ϱ ( ξ ) + ( ξ ϱ ( ξ ) ) 2 + c g ( ξ ) + ( ξ g ( ξ ) ) 2 + c .
According to Lemma 2, we obtain
C ν , α k F ( ξ ) g ( ξ ) ,
and g is the best dominant. □
Theorem 4. 
Let g be convex such that g ( 0 ) = 1 . If
C ν , α k ( ξ ) g ( ξ ) + ξ g ( ξ ) , ξ ,
then C ν , α k ( ξ ) ξ g ( ξ ) , and this result is sharp.
Proof. 
Define the following function
ϱ ( ξ ) : = C ν , α k ( ξ ) ξ [ 1 , 1 ] .
A direct application of Lemma 1 yields
C ν , α k ( ξ ) = ξ ϱ ( ξ ) C ν , α k ( ξ ) = ϱ ( ξ ) + ξ ϱ ( ξ ) .
Thus, we introduce the following subordination:
ϱ ( ξ ) + ξ ϱ ( ξ ) g ( ξ ) + ξ g ( ξ ) .
Hence, we conclude that C ν , α k ( ξ ) ξ g ( ξ ) , and g is the best dominant. □
Theorem 5. 
If fulfills the subordination
( C ν , α k ( ξ ) ) 1 + ξ 1 ξ b , ξ , b > 0 ,
then
C ν , α k ( ξ ) ξ > ϵ , ϵ [ 0 , 1 ) .
Proof. 
Construct ϱ as in (6). Thus, by subordination possessions, we indicate that
( C ν , α k ( ξ ) ) = ξ ϱ ( ξ ) + ϱ ( ξ ) 1 + ξ 1 ξ b .
With the help of Lemma 1—i, there occurs a fixed number a > 0 with b = b ( a ) where
C ν , α k ( ξ ) ξ 1 + ξ 1 ξ a .
This leads to real conclusion ( C ν , α k ( ξ ) / ξ ) > ϵ , ϵ [ 0 , 1 ) .  □
Theorem 6. 
If fulfills the real inequality
( C ν , α k ( ξ ) ) C ν , α k ( ξ ) ξ > ( α 2 ) , ξ , α C
then C ν , α k ( ξ ) B k ( ν , α , ϵ ) .
Proof. 
Formulate ϱ as in (6). A clear evaluation gives
ϱ 2 ( ξ ) + 2 ϱ ( ξ ) · ξ ϱ ( ξ ) = 2 C ν , α k ( ξ ) ) C ν , α k ( ξ ) ξ > ( α ) .
By the advantage of Lemma 1—ii, there occurs a constant κ concerning on ( α ) where ( ϱ ( ξ ) ) > κ , this gives ( ϱ ( ξ ) ) > ϵ , ϵ [ 0 , 1 ) . By virtue of (7), it implies that C ν , α k ( ξ ) ) > ϵ and hence based on the idea of Noshiro-Warschawski and Kaplan Theorems, C ν , α k ( ξ ) is univalent and of bounded boundary rotation in ∪. □
Theorem 7. 
The set B k ( ν , α , ϵ ) is convex.
Proof. 
Suppose that i B k ( ν , α , ϵ ) , i = 1 , 2 achieve the formulas 1 ( ξ ) = ξ + n = 2 a n ξ n and 2 ( ξ ) = ξ + n = 2 b n ξ n respectively. It is adequate to show that the linear combination function
G ( ξ ) = w 1 1 ( ξ ) + w 2 2 ( ξ ) , ξ
belongs to B k ( ν , α , ϵ ) , where w 1 > 0 , w 2 > 0 and w 1 + w 2 = 1 .
By the definition of G ( ξ ) , a computation yields that
G ( ξ ) = ξ + n = 2 ( w 1 a n + w 2 b n ) ξ n
then under the formal C ν , α k , we obtain
C ν , α k G ( ξ ) = ξ + n = 2 ( w 1 a n + w 2 b n ) × ( 1 α ) C m + n 1 m + α κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) k ξ n .
By considering the derivative, we have
( C ν , α k G ( ξ ) ) = 1 + w 1 n = 2 n ( 1 α ) C m + n 1 m + α κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) k a n ξ n 1 + w 2 n = 2 n ( 1 α ) C m + n 1 m + α κ 1 ( ν , ξ ) + ( 1 ) n + 1 κ 0 ( ν , ξ ) κ 1 ( ν , ξ ) + κ 0 ( ν , ξ ) k b n ξ n 1 > 1 + w 1 ( ϵ 1 ) + w 2 ( ϵ 1 ) = ϵ .
 □

4. Applications

A set of complex differential equations is an assembly of differential equations with complex variables. The most important study in this direction is to establish the existence and uniqueness results. There are diffident types of techniques including the utility of majors and minors (or subordination and superordination concepts) (see [12]). Investigation of ODEs in the complex domain suggests the detection of novel transcendental special functions, which currently called a Briot–Bouquet differential equation (BBDE)
ω ( ξ ) + ( 1 ω ) ξ ( ( ξ ) ) ( ξ ) = ( ξ ) ,
( 0 ) = ( 0 ) , ω [ 0 , 1 ] , ξ , .
In this place, we shall generalize the BBDE into a symmetric BBDE by using SCDO. Numerous presentations of these comparisons in the geometric function model have recently achieved in [12].
Needham and McAllister [16] presented a two-dimensional complex holomorphic dynamical system, pleasing the 2-D form
ξ t = Θ ( ξ , ω ) ; ω t = Θ ( ξ , w ) , ξ , ω
and t is in any real interval. Development application of the BBDE seemed newly, with different approaches (see [17]) to solve the equation of electronic nano-shells (see [18]). Controlled by the situation effort of traditional shell theory, the transposition fields of the nano-shell take the dynamic system
ξ t = Θ ( ξ , ω ) + Θ θ ( ξ , ω ) ; ω t = Θ ( ξ , ω ) + Θ θ ( ξ ¯ , ω ¯ ) , ξ , ω ,
where θ is the angles between ξ and ω and their conjugates.
Our purpose is to generalize this class of equation by utilizing the SCDO and establish its properties by applying the subordination concept. In view of (2), we have the generalized BBDE
ω ( ξ ) + ( 1 ω ) ξ ( S ν k ( ξ ) ) S ν k ( ξ ) = ( ξ ) , ( 0 ) = ( 0 ) , ξ .
The subordination settings and alteration bounds for a session of SCDO specified in the following formula. A trivial resolution of (8) is given when ω = 1 . Consequently, our vision is to carry out the situation, and ω = 0 . We proceed to present the behavior of the solution of (8).
Theorem 8. 
For , α [ 0 , ) and ℏ is univalent convex in ∪ if
ξ ( S ν k ) S ν k ( ξ ) ( ξ ) , ξ
then
S ν k ( ξ ) ξ exp 0 ξ ( ( ξ ) ) 1 d ,
whereis a Schwarz function in ∪. In addition, we have
| ξ | exp 0 1 ( ( σ ) ) 1 σ d σ | Δ α m ( ξ ) | | ξ | exp 0 1 ( ( σ ) ) 1 σ d σ .
Proof. 
The subordination in (9) implies that there occurs a Schwarz function ⊤ such that
ξ ( S ν k ( ξ ) ) S ν k ( ξ ) = ( ( ξ ) ) , ξ .
This yields the inequality
ξ ( S ν k ( ξ ) ) S ν k ( ξ ) 1 ξ = ( ( ξ ) ) 1 ξ .
By making the integrated operating, we have
log S ν k ( ξ ) ξ = 0 ξ ( ( ) ) 1 d .
Consequently, we have
log S ν k ( ξ ) = 0 ξ ( ( ) ) 1 d log ( ξ ) .
A calculation brings the next subordination relation
S ν k ( ξ ) ξ exp 0 ξ ( ( ) ) 1 d .
Moreover, the function translates the disk 0 | ξ | σ 1 into a convex symmetric domain toward the x-axis; in other words, we have
( σ | ξ | ) ( ( ( σ ξ ) ) ) ( σ | ξ | ) , σ ( 0 , 1 ] , | ξ | σ ,
which implies the inequalities:
( σ ) ( σ | ξ | ) , ( σ | ξ | ) ( σ )
and
0 1 ( ( σ | ξ | ) ) 1 σ d σ 0 1 ( ( σ ) ) 1 σ d σ 0 1 ( ( σ | ξ | ) ) 1 η d σ .
By employing (10) and the last inequality, we arrive at
0 1 ( ( σ | ξ | ) ) 1 σ d σ log | S ν k ( ξ ) ξ | 0 1 ( ( σ | ξ | ) ) 1 σ d σ .
This equivalence to the fact
exp 0 1 ( ( σ | ξ | ) ) 1 σ d σ | S ν k ( ξ ) ξ | exp 0 1 ( ( σ | ξ | ) ) 1 σ d σ .
 □
We note that the condition of Theorem 8, which the BB formula subordinates by a convex univalent function can be replaced by a general condition as follows:
Theorem 9. 
Suppose that , α [ 0 , ) and 0 < υ 1 . If
ξ ( S ν k ( ξ ) ) ξ S ν k ( ξ ) 2 υ ξ 1 + ξ , ξ
then
| S ν k ( ξ ) ξ 1 | υ .
Moreover, define the term
υ : = 1 ( 1 r ) v , 0 < r < 1 ,
for some positive constant v , then
| S ν k ( ξ ) ξ | v + 1 ( 1 r ) v + 1 .
Proof. 
In view of Lemma 3, we have the subordination inequality
S ν k ( ξ ) ξ 1 + υ ξ .
Since the result is sharp, then directly, we obtain the inequality (13). Consequently, by ([19], lemma 5.1.3), we have the inequality (14). □

Author Contributions

Conceptualization, R.M.E.; Formal analysis, R.W.I.; Funding acquisition, R.M.E.; Methodology, R.W.I.; Project administration, R.M.E.; Writing—review and editing, S.J.O. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Acknowledgments

The authors would like to express their thanks to the reviewers to provide us deep comments.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Duren, P. Univalent Functions; Grundlehren der mathematischen Wissenschaften; Springer-Verlag New York Inc.: New York, NY, USA, 1983; Volume 259, ISBN 0-387-90795-5. [Google Scholar]
  2. Goodman, A.W. Univalent Functions; Mariner Pub Co.: Bostan, MA, USA, 1983; ISBN 978-0936166100. [Google Scholar]
  3. Sàlxaxgean, G.S. Subclasses of Univalent Functions, Complex Analysis-Fifth Romanian-Finnish Seminar, Part 1 (Bucharest, 1981); Lecture Notes in Math; Springer: Berlin, Germany, 1983; Volume 1013, pp. 362–372. [Google Scholar]
  4. Al-Oboudi, F.M. On univalent functions defined by a generalized Sàlàgean operator. Int. J. Math. Math. Sci. 2004, 27, 1429–1436. [Google Scholar] [CrossRef] [Green Version]
  5. Ibrahim, R.W. Operator Inequalities Involved Wiener–Hopf Problems in the Open Unit Disk. In Differential and Integral Inequalities; Springer: Cham, Switzerland, 2019; Volume 13, pp. 423–433. [Google Scholar]
  6. Ibrahim, R.W.; Darus, M. Subordination inequalities of a new S. Sàlàgean difference operator. Int. J. Math. Comput. Sci. 2019, 14, 573–582. [Google Scholar]
  7. Ibrahim, R.W.; Jahangiri, J.M. Conformable differential operator generalizes the Briot-Bouquet differential equation in a complex domain. AIMS Math. 2019, 6, 1582–1595. [Google Scholar] [CrossRef]
  8. Ibrahim, R.W.; Darus, M. New Symmetric Differential and Integral Operators Defined in the Complex Domain. Symmetry 2019, 7, 906. [Google Scholar] [CrossRef] [Green Version]
  9. Ibrahim, R.W.; Darus, M. Univalent functions formulated by the Salagean-difference operator. Int. J. Anal. Appl. 2019, 4, 652–658. [Google Scholar]
  10. Ibrahim, R.W. Regular classes involving a generalized shift plus fractional Hornich integral operator. Bol. Soc. Parana. Mat. 2020, 38, 89–99. [Google Scholar] [CrossRef] [Green Version]
  11. Anderson, D.R.; Ulness, D.J. Newly defined conformable derivatives. Adv. Dyn. Syst. Appl. 2015, 10, 109–137. [Google Scholar]
  12. Miller, S.S.; Mocanu, P.T. Differential Subordinations: Theory and Applications; CRC Press: Boca Raton, FL, USA, 2000. [Google Scholar]
  13. Tuneski, N.; Obradovic, M. Some properties of certain expressions of analytic functions. Comput. Math. Appl. 2011, 62, 3438–3445. [Google Scholar] [CrossRef] [Green Version]
  14. Lupas, A. Some differential subordinations using Ruscheweyh derivative and S. Sàlàgean operator. Adv. Differ. Equ. 2013, 150, 1–11. [Google Scholar]
  15. Janowski, W. Some extremal problems for certain families of analytic functions. Ann. Pol. Math. 1973, 28, 297–326. [Google Scholar] [CrossRef] [Green Version]
  16. Needham, D.J.; McAllister, S. Centre families in two-dimensional complex holomorphic dynamical systems. Proc. R. Soc. Lond. Ser. 1998, 454, 2267–2278. [Google Scholar] [CrossRef]
  17. Ebrahimi, F.; Mohammadi, K.; Barouti, M.M.; Habibi, M. Wave propagation analysis of a spinning porous graphene nanoplatelet-reinforced nanoshell. Waves Random Complex Media 2019, 27, 1–27. [Google Scholar] [CrossRef]
  18. Habibi, M.; Mohammadgholiha, M.; Safarpour, H. Wave propagation characteristics of the electrically GNP-reinforced nanocomposite cylindrical shell. J. Braz. Soc. Mech. Sci. Eng. 2019, 41, 221. [Google Scholar] [CrossRef]
  19. Hormander, L. Linear Partial Differential Operators; Springer: Berlin/Heidelberg, Germany, 1963. [Google Scholar]

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MDPI and ACS Style

Ibrahim, R.W.; Elobaid, R.M.; Obaiys, S.J. Symmetric Conformable Fractional Derivative of Complex Variables. Mathematics 2020, 8, 363. https://doi.org/10.3390/math8030363

AMA Style

Ibrahim RW, Elobaid RM, Obaiys SJ. Symmetric Conformable Fractional Derivative of Complex Variables. Mathematics. 2020; 8(3):363. https://doi.org/10.3390/math8030363

Chicago/Turabian Style

Ibrahim, Rabha W., Rafida M. Elobaid, and Suzan J. Obaiys. 2020. "Symmetric Conformable Fractional Derivative of Complex Variables" Mathematics 8, no. 3: 363. https://doi.org/10.3390/math8030363

APA Style

Ibrahim, R. W., Elobaid, R. M., & Obaiys, S. J. (2020). Symmetric Conformable Fractional Derivative of Complex Variables. Mathematics, 8(3), 363. https://doi.org/10.3390/math8030363

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