Next Article in Journal
A Symmetric Extensible Protocol for Quantum Secret Sharing
Next Article in Special Issue
Some Hermite–Hadamard and Hermite–Hadamard–Fejér Type Fractional Inclusions Pertaining to Different Kinds of Generalized Preinvexities
Previous Article in Journal
Multi-Type Object Tracking Based on Residual Neural Network Model
Previous Article in Special Issue
Bi-Univalent Problems Involving Certain New Subclasses of Generalized Multiplier Transform on Analytic Functions Associated with Modified Sigmoid Function
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

Some New Fractional Integral Inequalities Pertaining to Generalized Fractional Integral Operator

by
Omar Mutab Alsalami
1,
Soubhagya Kumar Sahoo
2,3,
Muhammad Tariq
4,5,
Asif Ali Shaikh
4,
Clemente Cesarano
6 and
Kamsing Nonlaopon
7,*
1
Department of Electrical Engineering, College of Engineering, Taif University, P.O. Box 11099, Taif 21944, Saudi Arabia
2
Department of Mathematics, Institute of Technical Education and Research, Siksha ’O’ Anusandhan University, Bhubaneswar 751030, India
3
Department of Mathematics, Aryan Institute of Engineering and Technology, Bhubaneswar 752050, India
4
Department of Basic Sciences and Related Studies, Mehran University of Engineering and Technology, Jamshoro 76062, Pakistan
5
Department of Mathematics, Baluchistan Residential College Loralai, Loralai 84800, Pakistan
6
Section of Mathematics, International Telematic University Uninettuno, Corso Vittorio Emanuele II, 39, 00186 Roma, Italy
7
Department of Mathematics, Faculty of Science, Khon Kaen University, Khon Kaen 40002, Thailand
*
Author to whom correspondence should be addressed.
Symmetry 2022, 14(8), 1691; https://doi.org/10.3390/sym14081691
Submission received: 25 July 2022 / Revised: 9 August 2022 / Accepted: 10 August 2022 / Published: 15 August 2022
(This article belongs to the Special Issue Symmetry in Functional Equations and Analytic Inequalities III)

Abstract

:
Integral inequalities make up a comprehensive and prolific field of research within the field of mathematical interpretations. Integral inequalities in association with convexity have a strong relationship with symmetry. Different disciplines of mathematics and applied sciences have taken a new path as a result of the development of new fractional operators. Different new fractional operators have been used to improve some mathematical inequalities and to bring new ideas in recent years. To take steps forward, we prove various Grüss-type and Chebyshev-type inequalities for integrable functions in the frame of non-conformable fractional integral operators. The key results are proven using definitions of the fractional integrals, well-known classical inequalities, and classical relations.

1. Introduction

Fractional calculus theory gained popularity and was employed as a mathematical tool in a variety of pure and practical fields. This approach has previously been used in a variety of industries with some impressive results. It has been used in medicine [1], physics [2], modelling of diseases [3,4], nanotechnology [5], fluid mechanics [6], bioengineering [7], epidemiology [8], economics [9], and control systems [10].
In applied mathematics, inequalities and their applications are crucial. Various fractional operators were used to show a collection of integral inequalities and their generalizations (see [11,12,13,14,15,16,17]). To follow this trend, we use a generalized non-conformable fractional integral operator to show an improved version of the Grüss-type inequality. G. Grüss presented the well-known Grüss-type inequality in 1935, which was linked to the Chebyshev’s inequality; see [18].
1 κ ϱ ϱ κ S ( u ) Z ( u ) du 1 κ ϱ ϱ κ S ( u ) du 1 κ ϱ ϱ κ Z ( u ) du ( B A ) ( D C ) 4 .
Provided that S and Z are two integrable functions on [ ϱ , κ ] , satisfying the condition,
A S ( u ) B , C Z ( u ) D , A , B , C , D R , u [ ϱ , κ ] .
For integrable functions, various types of inequalities have been established, but the Grüss inequality has been the focus of many studies as many scholars have examined it extensively. Chaos, bio-sciences, fluid dynamics, engineering, meteorology, biochemistry, vibration analysis, aerodynamics, and many other scientific fields benefit from this inequality. See [19,20,21,22,23,24] for a steady growth of interest in such a field of study to address the difficulties of various applications of these variants.
T ( S , Z ) = 1 κ ϱ ϱ κ S ( u ) Z ( u ) d u 1 κ ϱ ϱ κ S ( u ) d u 1 κ ϱ ϱ κ Z ( u ) d u ,
where S and Z are two integral functions that are synchonous on [ ϱ , κ ] , given as
( S ( u ) S ( y ) ) ( Z ( u ) Z ( y ) ) 0 ,
for any u , y [ ϱ , κ ] ; then, the Chebyshev inequality states that T ( S , Z ) 0 .
The interest in inequality (1) has been evoked by the researcher. There are numerous recent studies in the literature on theoretical inequalities. In the approach of unital 2-positive linear maps, Balasubramanian [25] worked on the idea of the Grüss-type inequality. Pecaric [26] looked at certain Grüss inequality extensions and applications using weighted Ozeki’s inequality, which is a supplement to the Cauchy–Schwartz inequality. Butt [27] contributed a paper on the Jensen–Grüss-type inequality and its application to the Zipf–Mandelbrot law. The extended generalized Mittag–Leffler function was used by Akdemir [28] to investigate several Grüss-type integral inequalities for fractional integral operators. Akdemir [29] also used the generalized fractional integral operator to analyze several Grüss-type inequalities. Using the generalized Katugampola fractional integral operator, Aljaaidi [30] investigated and proved various Grüss-type inequalities.
Employing the concept of time scales, Sarikaya [31] wrote a remark on Grüss-type inequalities. Pachpatte [32] looked at certain differential function Chebyshev–Grüss inequalities. In the style of a generalized K-fractional integral operator, Noor [33] explained various Grüss-type inequalities. Using the Riemann–Liouville fractional integral operator, Dahmani [34] showed several expansions of the Grüss-type integral inequality. Chinchane [35] presented a paper that used the Hadamard fractional integral operator to create a novel Grüss-type inequality. Sarikaya [36] employed a variation of Pompeiu’s mean value theorem to develop a Grüss-type inequality. Kalla [37] investigated Grüss type inequalities for a hypergeometric fractional integral operator. E. Set [38] worked on the novel Grüss type inequalities via conformable fractional integral operator. The Riemann–Liouville fractional integral operator was used to solve the following integral inequality given by Dahmani et al. [34].
Theorem 1.
Let S and Z be two integrable functions on ( 0 , ) satisfying the condition
A S ( u ) B , C Z ( u ) D , A , B , C , D R , u [ ϱ , κ ] ,
on ( 0 , ) ; then, η > 0 , we have
w η Γ ( η + 1 ) J η S Z ( w ) J η S ( w ) J η Z ( w ) w η 2 Γ ( η + 1 ) 2 ( B A ) ( D C ) .
The paper is arranged as follows: In Section 2, we give some known concepts. In Section 3, we obtain some Grüss-type fractional integral inequalities on the basis of new lemmas with the help of the Cauchy–Schwarz inequality. In Section 4, we investigate some other fractional integral inequalities involving non-conformable fractional integral operators with the help of Young’s inequality. Section 5 deals with Chebyshev-type inequalities. A brief conclusion is given in Section 6.

2. Preliminaries

Definition 1
([39]). For each S L [ ξ , ϑ ] and 0 < ξ < ϑ , we define
N 3 J u η S ( x ) = u x ϑ η S ( ϑ ) d ϑ ,
for every x , u [ ξ , ϑ ] and η R .
Definition 2
([39]). For each function S L [ ξ , ϑ ] , we define the fractional integrals
N 3 J ξ + η S ( x ) = ξ x x ϑ η S ( ϑ ) d ϑ ,
N 3 J ϑ η S ( x ) = x ϑ ϑ x η S ( ϑ ) d ϑ ,
for every x [ ξ , ϑ ] and η R .
Remark 1.
In the above definitions, if we put η = 0 then we have the classical integrals, which are represented by N 3 J ξ + η S ( x ) = N 3 J ϑ η S ( x ) = ξ ϑ S ( ϑ ) d ϑ .

3. Fractional Inequality of Grüss Type

In this section, first, we prove some new integrable equalities; then, using these equalities and the Cauchy–Schwarz inequality, our main findings are presented.
Lemma 1.
Let the integrable function on ( 0 , ) be S with A , B R ; then, w > 0 a n d η > 0 , the following equality holds true:
( w ϱ ) η η N 3 J ϱ + η S 2 ( w ) + N 3 J ϱ + η S ( w ) 2 = B ( w ϱ ) η η N 3 J ϱ + η S ( w ) N 3 J ϱ + η S ( w ) A ( w ϱ ) η η ( w ϱ ) η η N 3 J ϱ + η ( B S ( w ) ) ( S ( w ) A ) .
Proof. 
Let A , B R and S be an integrable function on ( 0 , ) μ , ρ ( 0 , ) ; then, we have
( B S ( ρ ) ) ( S ( μ ) A ) + ( B S ( μ ) ) ( S ( ρ ) A ) ( B S ( μ ) ) ( S ( μ ) A ) ( B S ( ρ ) ) ( S ( ρ ) A ) = S 2 ( μ ) + S 2 ρ + 2 S ( μ ) S ( ρ ) .
If we multiply both sides of (6) by ( w μ ) η 1 and integrate the resultant equality with respect to μ , we obtain
B S ( ρ ) N 3 J ϱ + η S ( w ) A ( w ϱ ) η η + B ( w ϱ ) η η N 3 J ϱ + η S ( w ) S ( ρ ) A N 3 J ϱ + η ( B S ( w ) S ( w ) A ) ( B S ( ρ ) ) ( S ( ρ ) A ) ( w ϱ ) η η = N 3 J ϱ + η S 2 ( w ) + ( w ϱ ) η η S 2 ( ρ ) + 2 S ( ρ ) N 3 J ϱ + η S ( w ) .
Upon multiplication of both sides of (7) by ( w ρ ) η 1 and integration of the resultant equality with respect to ρ , we yield
N 3 J ϱ + η S ( w ) A ( w ϱ ) η η a w ( w ρ ) η 1 ( B S ( ρ ) ) d ρ + B ( w ϱ ) η η N 3 J ϱ + η S ( w ) a w ( w ρ ) η 1 ( S ( ρ ) A ) d ρ N 3 J ϱ + η ( B S ( w ) ) ( S ( w ) A ) a w ( w ρ ) η 1 ( B S ( ρ ) ) d ρ ( w η ) η η a w ( w ρ ) η 1 ( B S ( ρ ) ) ( S ( ρ ) A ) d ρ = ( w η ) η η N 3 J ϱ + η S 2 ( w ) + ( w ϱ ) η η N 3 J ϱ + η S 2 ( w ) + 2 N 3 J ϱ + η S ( w ) N 3 J ϱ + η S ( w ) ,
This led us to the proof of Lemma 1. □
Theorem 2.
Let the integrable functions on [ 0 , ) , be S and Z satisfying the condition
A S ( w ) B , C Z ( w ) D , A , B , C , D R , w [ 0 , ) .
Then,
( w η ) η η N 3 J ϱ + η ( S Z ) ( w ) N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) ( w η ) η 2 η 2 ( B A ) ( D C ) .
holds true.
Proof. 
Let S and Z be two given integrable function on [ 0 , ) , with the condition
A S ( w ) B , C Z ( w ) D , A , B , C , D R , w [ 0 , ) .
If we define
H ( μ , ρ ) = ( S ( μ ) S ( ρ ) ) ( Z ( μ ) Z ( ρ ) ) .
It readily follows that
H ( μ , ρ ) = ( S ( μ ) Z ( μ ) S ( μ ) Z ( ρ ) S ( ρ ) Z ( μ ) + S ( ρ ) Z ( ρ ) .
Then, multiplying the above equality by ( w μ ) η 1 and integrating the resultant equality with respect to μ , we have
a w ( w μ ) η 1 H ( μ , ρ ) d μ = N 3 J ϱ + η S Z ( w ) S ( ρ ) N 3 J ϱ + η Z ( w ) Z ( ρ ) N 3 J ϱ + η S ( w ) + S ( ρ ) Z ( ρ ) ( w ϱ ) η η .
Again, multiplying the above equality by ( w ρ ) η 1 and then integrating the with respect to ρ , we have
a w a w ( w μ ) η 1 ( w ρ ) η 1 H ( μ , ρ ) d μ d ρ = 2 ( w ϱ ) η η N 3 J ϱ + η S Z ( w ) N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) .
Employing the Cauchy–Schwarz inequality, we obtain
( w ϱ ) η η N 3 J ϱ + η S Z ( w ) N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) 2 ( w ϱ ) η η N 3 J ϱ + η S 2 ( w ) N 3 J ϱ + η S ( w ) 2 ( w ϱ ) η η N 3 J ϱ + η Z 2 ( w ) N 3 J ϱ + η Z ( w ) 2 .
Since, ( B S ( w ) ) ( S ( w ) A ) 0 and ( D Z ( w ) ) ( Z ( w ) C ) 0 , we consequently have
( w ϱ ) η η N 3 J ϱ + η ( B S ( w ) ) ( S ( w ) A ) 0 ,
and
( w ϱ ) η η N 3 J ϱ + η ( D Z ( w ) ) ( Z ( w ) C ) 0 .
Thus,
( w ϱ ) η η N 3 J ϱ + η S 2 ( w ) N 3 J ϱ + η S ( w ) 2 B ( w ϱ ) η η N 3 J ϱ + η S ( w ) N 3 J ϱ + η S ( w ) A ( w ϱ ) η η .
Additionally,
( w ϱ ) η η N 3 J ϱ + η Z 2 ( w ) N 3 J ϱ + η Z ( w ) 2 D ( w ϱ ) η η N 3 J ϱ + η Z ( w ) N 3 J ϱ + η Z ( w ) C ( w ϱ ) η η .
From Lemma 1 and the above inequalities (10) and (14), we can conclude that
( w ϱ ) η η N 3 J ϱ + η S Z ( w ) N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) 2 B ( w ϱ ) η η N 3 J ϱ + η S ( w ) N 3 J ϱ + η S ( w ) A ( w ϱ ) η η × D ( w ϱ ) η η N 3 J ϱ + η Z ( w ) N 3 J ϱ + η Z ( w ) C ( w ϱ ) η η .
Now, using the inequality 4 b c ( b + c ) 2 , b , c R , we obtain
4 B ( w ϱ ) η η N 3 J ϱ + η S ( w ) N 3 J ϱ + η S ( w ) A ( w ϱ ) η η ( w η ) η η ( B A ) 2 ,
and
4 D ( w ϱ ) η η N 3 J ϱ + η Z ( w ) N 3 J ϱ + η Z ( w ) C ( w ϱ ) η η ( w η ) η η ( D C ) 2 .
The proof of Theorem 7 is completed from the above developments (Equations (15)–(17)). □
Lemma 2.
Let the integrable functions on [ 0 , ) be S and Z ; then, the following identity for all w 0 , η 0 and β 0 holds true:
( w ϱ ) η η N 3 J ϱ + β S Z ( w ) + ( w ϱ ) β β N 3 J ϱ + η S Z ( w ) N 3 J ϱ + η S ( w ) N 3 J ϱ + β Z ( w ) N 3 J ϱ + η Z ( w ) N 3 J ϱ + β S ( w ) 2 ( w ϱ ) η η N 3 J ϱ + β S 2 ( w ) + ( w ϱ ) β β N 3 J ϱ + η S 2 ( w ) 2 N 3 J ϱ + β S ( w ) N 3 J ϱ + η + S ( w ) × ( w ϱ ) η η N 3 J ϱ + β Z 2 ( w ) + ( w ϱ ) β β N 3 J ϱ + η Z 2 ( w ) 2 N 3 J ϱ + η Z ( w ) N 3 J ϱ + β + Z ( w )
Proof. 
Multiplying (9) by ( w ρ ) β 1 , then integrating the resultant with respect to ρ , and applying the Cauchy–Schwarz inequality, we have the desired inequality (18). □
Lemma 3.
Let the integrable functions on [ 0 , ) be S and A , B R ; then, for all w 0 , a l p h a 0 and β 0 , the following equality holds true:
( w ϱ ) η η N 3 J ϱ + β S 2 ( w ) + ( w ϱ ) β β N 3 J ϱ + η S 2 ( w ) + 2 N 3 J ϱ + η S ( w ) N 3 J ϱ + β S ( w ) = B ( w ϱ ) η η N 3 J ϱ + η S ( w ) N 3 J ϱ + β S ( w ) A ( w ϱ ) β β + B ( w ϱ ) β β N 3 J ϱ + β S ( w ) N 3 J ϱ + η S ( w ) A ( w ϱ ) η η ( w ϱ ) η η N 3 J ϱ + β ( B S ( w ) ) ( S ( w ) A ) ( w ϱ ) β β N 3 J ϱ + η ( B S ( w ) ) ( S ( w ) A ) .
Proof. 
Multiplying (7) by ( w ρ ) β 1 and then integrating the resulting identity with respect to ρ , we have
N 3 J ϱ + η S ( w ) A ( w ϱ ) η η a w ( w ρ ) ( β 1 ) ( B S ( ρ ) ) d ρ + B ( w ϱ ) η η N 3 J ϱ + η S ( w ) a w ( S ( ρ ) A ) ( w ρ ) ( β 1 ) d ρ N 3 J ϱ + η ( B S ( w ) ( S ( w ) A ) ( w ρ ) ( β 1 ) d ρ ( w ϱ ) η η a w ( B S ( ρ ) ) ( S ( ρ ) A ) d ρ = ( w ϱ ) β β N 3 J ϱ + η S 2 ( w ) + ( w ϱ ) η η N 3 J ϱ + β S 2 ( w ) + 2 N 3 J ϱ + η S ( w ) N 3 J ϱ + β S ( w ) .
The above developments completes the proof of Lemma 3. □
Theorem 3.
Let S and Z be two integrable function on [ 0 , ) satisfying the condition
A S ( w ) B , C Z ( w ) D , A , B , C , D R , w [ 0 , ) ,
we have
( w ϱ ) η η N 3 J ϱ + β S Z ( w ) + ( w ϱ ) β β N 3 J ϱ + η S Z ( w ) N 3 J ϱ + η S ( w ) N 3 J ϱ + β Z ( w ) N 3 J ϱ + β S ( w ) N 3 J ϱ + β Z ( w ) 2 B ( w ϱ ) η η N 3 J ϱ + η S ( w ) N 3 J ϱ + β S ( w ) A ( w ϱ ) β β + B ( w ϱ ) β β N 3 J ϱ + β S ( w ) N 3 J ϱ + η S ( w ) A ( w ϱ ) β β × D ( w ϱ ) η η N 3 J ϱ + η Z ( w ) N 3 J ϱ + β Z ( w ) C ( w ϱ ) β β + D ( w ϱ ) β β N 3 J ϱ + β Z ( w ) N 3 J ϱ + η Z ( w ) C ( w ϱ ) β β .
Proof. 
Since ( B S ( w ) ) ( S ( w ) A ) 0 and ( D Z ( w ) ) ( Z ( w ) C ) 0 , then we can write
( w ϱ ) η η N 3 J ϱ + β ( B S ( w ) ) ( S ( w ) A ) ( w ϱ ) β β N 3 J ϱ + η ( B S ( w ) ) ( S ( w ) A ) 0 ,
and
( w ϱ ) η η N 3 J ϱ + β ( D Z ( w ) ) ( Z ( w ) C ) ( w ϱ ) β β N 3 J ϱ + η ( D Z ( w ) ) ( Z ( w ) C ) 0 .
If we apply Lemma 3 for S and Z , with Lemma 2 and Equations (19) and (20), we have the desired Theorem 3. □

4. Certain New Fractional Integral Inequalities

Here, we present some new type of inequalities (Theorems 4–6) pertaining to non-conformable fractional integral operator.
Theorem 4.
Let the positive functions defined on [ 0 , ) be S and Z . Then, the inequalities holds:
(i) 
1 p N 3 J ϱ + η ( S ) p + 1 q N 3 J ϱ + η ( Z ) q ( w η ) η η 1 N 3 J ϱ + η ( S ) N 3 J ϱ + η ( Z ) .
(ii) 
1 p N 3 J ϱ + η ( S ) p N 3 J ϱ + η ( Z ) p + 1 q N 3 J ϱ + η ( S ) q N 3 J ϱ + η ( Z ) q N 3 J ϱ + η ( S Z ) 2 .
(iii) 
1 p N 3 J ϱ + η ( S ) p N 3 J ϱ + η ( Z ) q + 1 q N 3 J ϱ + η ( S ) q N 3 J ϱ + η ( Z ) p N 3 J ϱ + η ( S Z p 1 ) N 3 J ϱ + η ( S Z q 1 ) .
(iv) 
N 3 J ϱ + η ( S ) p N 3 J ϱ + η ( Z ) q N 3 J ϱ + η ( S Z ) N 3 J ϱ + η S p 1 Z q 1 , where for p , q > 1 , 1 p + 1 q = 1 ,
Proof. 
From Young’s inequality, we have
1 p u p + 1 q v q uv , for   all u , v 0 , p , q > 1 , 1 p + 1 q = 1 .
If we choose, u = S ( μ ) and v = Z ( ρ ) , μ , ρ > o , then
1 p ( S ( μ ) ) p + 1 q ( Z ( ρ ) ) q S ( μ ) Z ( ρ ) , S ( μ ) Z ( ρ ) 0 .
Multiplication of inequality (21) by ( w μ ) η 1 , and integrating the resultant inequality with respect to μ , we get
1 p a w ( w μ ) η 1 ( S ( μ ) ) p d μ + 1 q Z ( ρ ) q a w ( w μ ) η 1 d μ Z ( ρ ) a w ( w μ ) η 1 S ( μ ) d μ .
Consequently,
1 p N 3 J ϱ + η ( S ( w ) ) p + ( w η ) η q η Z ( ρ ) q Z ( ρ ) N 3 J ϱ + η ( S ( w ) ) .
Analogously, multiplying inequality (23) by ( w ρ ) η 1 and integrating the obtained identity, we obtain
( w η ) η p η N 3 J ϱ + η ( S ( w ) ) p + ( w η ) η q η N 3 J ϱ + η ( Z ( w ) ) q N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) .
This readily follows:
( w η ) η η 1 p N 3 J ϱ + η ( S ( w ) ) p + 1 q N 3 J ϱ + η ( Z ( w ) ) q N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) .
Additionally,
1 p N 3 J ϱ + η ( S ( w ) ) p + 1 q N 3 J ϱ + η ( Z ( w ) ) q ( w η ) η η 1 N 3 J ϱ + η S ( w ) N 3 J ϱ + η Z ( w ) ,
which implies ( i ) . Similarly, we can prove the rest of the inequalities by making the correct choice of parameters as follows:
For ( i i ) U = S ( μ ) Z ( ρ ) , v = S ( ρ ) Z ( μ ) .
For ( i i i ) U = S ( μ ) Z ( μ ) , v = S ( ρ ) Z ( ρ ) , Z ( μ ) , Z ( ρ ) 0 .
For ( i v ) U = S ( ρ ) S ( μ ) , v = Z ( ρ ) Z ( μ ) , Z ( μ ) , Z ( ρ ) 0 .  □
Theorem 5.
Let the positive functions defined on [ 0 , ) be S and Z . Then, the following inequalities hold true:
( i )
1 p N 3 J ϱ + η ( S ) p N 3 J ϱ + η ( Z ) 2 + 1 q N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η ( Z ) q N 3 J ϱ + η ( S Z ) N 3 J ϱ + η ( S 2 q Z 2 p ) .
( i i )
1 p N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η ( Z ) q + 1 q N 3 J ϱ + η ( S ) q N 3 J ϱ + η ( Z ) 2 N 3 J ϱ + η ( S 2 q Z 2 p ) N 3 J ϱ + η ( S p 1 Z q 1 ) .
( i i i )
N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η 1 p Z q + 1 q Z p N 3 J ϱ + η ( S 2 p Z ) N 3 J ϱ + η ( S 2 q Z ) ,
for p , q > 1 satisfying 1 p + 1 q = 1 .
Proof. 
We can prove the results following similar procedures as in the previous Theorem 4 with an appropriate choice of parameters:
( i )
U = S ( μ ) Z 2 p ( ρ ) , V = S 2 q ( ρ ) Z ( μ ) .
( i i )
U = S 2 p ( μ ) S ( ρ ) , V = Z 2 q ( μ ) Z ( ρ ) , S ( ρ ) , Z ( ρ ) 0 .
( i i i )
U = S 2 p ( μ ) Z ( ρ ) , V = S 2 q ( μ ) Z ( ρ ) , Z ( ρ ) 0 .
Theorem 6.
Let the positive functions defined on [ 0 , ) be S and Z . For w > 0 with conditions
A min 0 μ w S ( μ ) Z ( μ ) , B = max 0 μ w S ( μ ) Z ( μ ) ,
the following inequalities hold true:
( i )
0 N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η ( Z ) 2 ( A + B ) 2 4 A B N 3 J ϱ + η ( S Z ) 2 .
( i i )
0 N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η ( Z ) 2 N 3 J ϱ + η ( S Z ) ( B A ) 2 4 A B N 3 J ϱ + η ( S Z ) .
( i i i )
0 N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η ( Z ) 2 N 3 J ϱ + η ( S Z ) 2 ( B A ) 2 4 A B N 3 J ϱ + η ( S Z ) 2 .
Proof. 
From (26) and
S ( μ ) Z ( μ ) A B S ( μ ) Z ( μ ) Z 2 ( μ ) 0 , 0 μ w ,
we have
S 2 ( μ ) + A B Z 2 ( μ ) ( A + B ) S ( μ ) Z ( μ ) .
Multiplying the above inequality (28) by ( w μ ) η 1 and then integrating the obtained result with respect to μ , we get
a w ( w μ ) η 1 S 2 ( μ ) d μ + A B a w ( w μ ) η 1 Z 2 ( μ ) d μ ( A + B ) a w ( w μ ) η 1 S ( μ ) S ( μ ) .
This implies
N 3 J ϱ + η ( S ) 2 ( w ) + A B N 3 J ϱ + η ( Z ) 2 ( w ) ( A + B ) N 3 J ϱ + η ( S Z ) ( w ) .
On the other hand, it follows from
A B > 0 ,   and   N 3 J ϱ + η ( S ) 2 A B N 3 J ϱ + η ( Z ) 2 2 0 2 N 3 J ϱ + η ( S ) 2 A B N 3 J ϱ + η ( Z ) 2 N 3 J ϱ + η ( S ) 2 + A B N 3 J ϱ + η ( Z ) 2 .
Then, from the last two inequalities (29) and (30), we obtain
4 A B N 3 J ϱ + η ( S ) 2 N 3 J ϱ + η ( Z ) 2 ( A + B ) 2 N 3 J ϱ + η ( S Z ) 2 ,
which readily follows (i); using the same operations as of (i), we can prove (ii) and (iii). □

5. Chebyshev-Type Inequalities

Theorem 7.
Let the integrable functions be L η , 0 + [ ϱ , κ ] , which are synchronous on [ ϱ , κ ] . Then,
N 3 J ϱ + η ( S Z ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) .
Proof. 
Since S and Z are synchronous on [ ϱ , κ ] , we have
( S ( a ) S ( b ) ) ( Z ( a ) Z ( b ) ) 0 a , b [ ϱ , κ ] ,
or equivalently
S ( a ) Z ( a ) + S ( b ) Z ( b ) S ( a ) Z ( b ) + S ( b ) Z ( a ) .
If we multiply both sides of the above inequality by ( κ a ) η , we have
S ( a ) Z ( a ) ( κ a ) η + S ( b ) Z ( b ) ( κ a ) η S ( a ) Z ( b ) ( κ a ) η + S ( b ) Z ( a ) ( κ a ) η .
Upon integrating the inequality obtained with respect to a, one has
ϱ κ ( κ a ) η S ( a ) Z ( a ) d a + S ( b ) Z ( b ) ϱ κ ( κ a ) η d a Z ( b ) ϱ κ ( κ a ) η S ( a ) d a + S ( b ) ϱ κ ( κ a ) η Z ( a ) d a .
From the above developments, we have
N 3 J ϱ + η ( S Z ) ( κ ) + ( κ ϱ ) 1 η 1 η S ( b ) Z ( b ) Z ( b ) N 3 J ϱ + η ( S ) ( κ ) + S ( b ) N 3 J ϱ + η ( Z ) ( κ ) .
Multiplying inequality (32) by ( κ b ) η and integrating the resultant inequality with respect to b, we obtain
N 3 J ϱ + η ( S Z ) ( κ ) ϱ κ ( κ b ) η d b + ( κ ϱ ) 1 η 1 η ϱ κ ( κ b ) η S ( b ) Z ( b ) d b N 3 J ϱ + η S ( κ ) ϱ κ ( κ b ) η Z ( b ) d b + N 3 J ϱ + η Z ( κ ) ϱ κ ( κ b ) η S ( b ) d b .
This readily gives
2 ( κ ϱ ) 1 η 1 η N 3 J ϱ + η ( S Z ) ( κ ) 2 N 3 J ϱ + η S ( κ ) N 3 J ϱ + η Z ( κ ) .
and we have the desired inequality ((31)). □
Remark 2.
Let S , Z L η , 0 be synchronous functions on [ ϱ , κ ] ; then, we have
N 3 J κ η ( S Z ) ( ϱ ) ( κ ϱ ) 1 η 1 η 1 N 3 J κ η S ( ϱ ) N 3 J κ η Z ( ϱ ) .
Remark 3.
If we take η = 0 in the above Theorem 7 (or in Remark 2), then the inequality (31) or inequality (33) reduces to the classical Chebyshev inequality.
Theorem 8.
Let S and Z be two function from L η , 0 + [ ϱ , κ ] L β , 0 + [ ϱ , κ ] , which are synchronous on [ ϱ , κ ] ; then, the following inequality holds true:
( κ ϱ ) 1 β 1 β N 3 J ϱ + η ( S Z ) ( κ ) + ( κ ϱ ) 1 η 1 η N 3 J ϱ + η ( S Z ) ( κ ) N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) + N 3 J ϱ + η ( Z ) ( κ ) N 3 J ϱ + η ( S ) ( κ ) .
Proof. 
Multiplying the inequality (32) by ( κ b ) β yields
( κ b ) β N 3 J ϱ + η ( S Z ) ( κ ) + ( κ ϱ ) 1 η 1 η ( κ b ) β S ( b ) Z ( b ) N 3 J ϱ + η ( S ) ( κ ) ( κ b ) β Z ( b ) + N 3 J ϱ + η ( Z ) ( κ ) ( κ b ) β S ( b ) .
Integrating the above inequality with respect to b yields inequality (34). □
Remark 4.
If we take η = β , then we obtain Theorem 7.
Theorem 9.
Let { S i } i = 1 , 2 , 3 , 4 , , n be a positive function L η , 0 + [ ϱ , κ ] ; then, we have
N 3 J ϱ + η i = 1 n S i S n + 1 ( κ ϱ ) 1 η 1 η n i = 1 n + 1 S i ( κ ) .
Proof. 
The theorem can be proven by the method of induction on n N . For n = 1, the above inequality trivially holds. For n = 2, since S 1 and S 2 are synchronous and positive functions and by the hypothesis of theorem 7, the inequality (35) readily follows. Now, let us assume that the inequality (35) holds true for n N . Let S = i = 1 n S i and Z = S n + 1 , as S and Z be increasing functions on [ ϱ , κ ] ; therefore, under the assumption of the inequality (31) and induction hypothesis, we have
N 3 J ϱ + η i = 1 n S i S n + 1 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η i = 1 n S i ( κ ) N 3 J ϱ + η S n + 1 ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η i = 1 n + 1 S i ( κ ) .
This concludes the desired proof. □
Theorem 10.
Let S , Z : [ 0 , ) R and S , Z L ϱ + [ ϱ , κ ] , be increasing and differentiable functions, respectively. Z is bounded below by m = inf w [ 0 , ) Z ( t ) ; then, we have
N 3 J ϱ + η ( S Z ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) m ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( w ) ( κ ) + m N 3 J ϱ + η ( w S ) ( κ ) ,
where w ( x ) = x is the identity function.
Proof. 
If h is differentiable and increasing on [ 0 , ) with P ( u ) = m u and h ( u ) = Z ( u ) P ( u ) . Then, applying the results of Theorem 31, we have
N 3 J ϱ + η ( S h ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( h ) ( κ ) = ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( P ) ( κ )
since N 3 J ϱ + η ( P ) ( κ ) = m N 3 J ϱ + η ( t ) ( κ ) and N 3 J ϱ + η ( S P ) ( κ ) = m N 3 J ϱ + η ( w S ) ( κ ) .
From the above developments, we have
N 3 J ϱ + η ( S Z ) ( κ ) = N 3 J ϱ + η ( S h ) ( κ ) + N 3 J ϱ + η ( S P ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( P ) ( κ ) + N 3 J ϱ + η ( S P ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) m ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( t ) ( κ ) + m N 3 J ϱ + η ( t S ) ( κ ) .
This completes the desired proof. □
Theorem 11.
Let S , Z : [ 0 , ) R and S , Z L ϱ + [ ϱ , κ ] , be increasing and differentiable functions, respectively. Z is bounded below by m = inf w [ 0 , ) Z ( t ) ; then, we have
Let S , Z : [ 0 , ) R and S , Z L ϱ + [ ϱ , κ ] be two differentiable functions. If S bounded below by m 1 = inf w [ 0 , ) S ( w ) and Z bounded below by m 2 = inf w [ 0 , ) Z ( w ) . Then we have
N 3 J ϱ + η ( S Z ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) m 2 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( w ) ( κ ) m 1 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( Z ) ( κ ) N 3 J ϱ + η ( w ) ( κ ) + m 1 m 2 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( w ) ( κ ) N 3 J ϱ + η ( w ) ( κ ) + m 2 N 3 J ϱ + η ( w S ) ( κ ) + m 1 N 3 J ϱ + η ( w Z ) ( κ ) m 1 m 2 N 3 J ϱ + η ( w 2 ) ( κ ) ,
where w ( u ) = u is the identity function.
Proof. 
Let h 1 and h 2 be differentiable and increasing functions on [ 0 , ) with P 1 ( u ) = m 1 u and h 1 ( u ) = Z ( u ) P 1 ( u ) ; similarly, P 2 ( u ) = m 2 u and h 2 ( u ) = Z ( u ) P 2 ( u ) . Then, applying the results of Theorem 7, we have
N 3 J ϱ + η ( h 1 h 2 ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( h 1 ) ( κ ) N 3 J ϱ + η ( h 2 ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( P 1 ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) N 3 J ϱ + η ( P 2 ) ( κ ) ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) N 3 J ϱ + η ( Z ) ( κ ) m 2 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( S ) ( κ ) O + I ϱ ( w ) ( κ ) m 1 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( Z ) ( κ ) N 3 J ϱ + η ( w ) ( κ ) m 1 m 2 ( κ ϱ ) 1 η 1 η 1 N 3 J ϱ + η ( w ) ( κ ) N 3 J ϱ + η ( w ) ( κ ) .
Moreover,
N 3 J ϱ + η ( h 1 P 2 ) ( κ ) = m 2 N 3 J ϱ + η ( w h 1 ) ( κ ) = m 2 N 3 J ϱ + η ( w S ) ( κ ) m 1 m 2 N 3 J ϱ + η ( w 2 ) ( κ ) .
Similarly,
N 3 J ϱ + η ( h 2 P 1 ) ( κ ) = m 1 N 3 J ϱ + η ( w Z ) ( κ ) m 1 m 2 N 3 J ϱ + η ( w 2 ) ( κ ) ,
and
N 3 J ϱ + η ( P 1 P 2 ) ( κ ) = m 1 m 2 N 3 J ϱ + η ( w 2 ) ( κ ) .
From the equality,
S Z = ( h 1 + P 1 ) ( h 2 + P 2 ) = h 1 h 2 + h 1 P 2 + h 2 P 1 + P 1 P 2 ,
we have
N 3 J ϱ + η ( S Z ) ( κ ) = N 3 J ϱ + η ( h 1 h 2 ) ( κ ) + N 3 J ϱ + η ( h 1 P 2 ) ( κ ) + N 3 J ϱ + η ( P 1 h 2 ) ( κ ) + N 3 J ϱ + η ( P 1 P 2 ) ( κ ) ,
and this equality together with (37)–(40) implies the required result. □
Remark 5.
If we take m 1 = 0 , then we obtain Theorem 10.
Remark 6.
If we consider S and Z , or S and Z instead of S and Z , under the assumptions of the synchronous functions, we will have new results with changes in the direction of the inequalities.

6. Conclusions

The Grüss inequality and the Chebyshev inequality have been extensively studied, and numerous generalizations, extensions, and variants of these two valuable inequalities have been established. Using a generalized integral operator, namely the non-conformable operator, several generalizations of the Grüss inequality as well as the Chebyshev-type inequality are presented in this paper. The findings provide novel approaches to the Grüss inequality thanks to the peculiarities of the fractional operator and some inequalities employed in the proofs. In future research work, different forms of fractional integral operators can be used to enhance the outcomes of researchers working on this topic.

Author Contributions

Conceptualization, O.M.A., S.K.S. and M.T.; methodology, S.K.S., M.T. and C.C.; software, O.M.A., S.K.S. and M.T.; validation, S.K.S., A.A.S. and K.N.; formal analysis, S.K.S., M.T., O.M.A. and C.C.; investigation, S.K.S. and M.T.; resources, S.K.S., K.N., C.C. and A.A.S.; writing—original draft preparation, S.K.S., M.T. and C.C.; writing—review and editing, O.M.A., S.K.S. and M.T.; supervision, S.K.S., K.N., C.C. and A.A.S.; project administration, S.K.S. and M.T.; funding acquisition, K.N. All authors have read and agreed to the published version of the manuscript.

Funding

This research was supported by the Fundamental Fund of Khon Kaen University, Thailand.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Acknowledgments

This research was supported by the Fundamental Fund of Khon Kaen University, Thailand.

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. El Shaed, M.A. Fractional Calculus Model of Semilunar Heart Valve Vibrations. In Proceedings of the International Mathematica Symposium, London, UK, 10–13 June 2003. [Google Scholar]
  2. Hilfer, R. Applications of Fractional Calculus in Physics; World Scientific: Singapore, 2000. [Google Scholar]
  3. Hoan, L.V.C.; Akinlar, M.A.; Inc, M.; Gomez-Aguilar, J.F.; Chu, Y.M.; Almohsen, B. A new fractional-order compartmental disease model. Alex. Eng. J. 2020, 59, 3187–3196. [Google Scholar] [CrossRef]
  4. Gul, N.; Bilal, R.; Algehyne, E.A.; Alshehri, M.G.; Khan, M.A.; Chu, Y.M.; Islam, S. The dynamics of fractional order Hepatitis B virus model with asymptomatic carriers. Alex. Eng. J. 2021, 60, 3945–3955. [Google Scholar] [CrossRef]
  5. Baleanu, D.; Güvenç, Z.B.; Machado, J.T. New Trends in Nanotechnology and Fractional Calculus Applications; Springer: New York, NY, USA, 2010. [Google Scholar]
  6. Kulish, V.V.; Lage, J.L. Application of fractional calculus to fluid mechanics. J. Fluids Eng. 2002, 124, 803–806. [Google Scholar] [CrossRef]
  7. Magin, R.L. Fractional Calculus in Bio-Engineering; Begell House Inc. Publishers: Danbury, CT, USA, 2006. [Google Scholar]
  8. Atangana, A. Application of fractional calculus to epidemiology. Fract. Dyn. 2016, 174–190, Warsaw, Poland: De Gruyter Open Poland. [Google Scholar]
  9. Chu, Y.M.; Bekiros, S.; Zambrano-Serrano, E.; Orozco-López, O.; Lahmiri, S.; Jahanshahi, H.; Aly, A.A. Artificial macro-economics: A chaotic discrete-time fractional-order laboratory model. Chaos Solitons Fract. 2021, 145, 110776. [Google Scholar] [CrossRef]
  10. Axtell, M.; Bise, M.E. Fractional calculus application in control systems. In Proceedings of the IEEE Conference on Aerospace and Electronics, Dayton, OH, USA, 21–25 May 1990; pp. 563–566. [Google Scholar]
  11. Sahoo, S.K.; Tariq, M.; Ahmad, H.; Aly, A.A.; Felemban, B.F.; Thounthong, P. Some Hermite-Hadamard-type fractional integral inequalities involving twice-differentiable mappings. Symmetry 2021, 13, 2209. [Google Scholar] [CrossRef]
  12. Rahman, G.; Abdeljawad, T.; Jarad, F.; Khan, A.; Nisar, K.S. Certain inequalities via generalized proportional Hadamard fractional integral operators. Adv. Diff. Eqs. 2019, 454, 1–10. [Google Scholar] [CrossRef]
  13. Rashid, S.; Abdeljawad, T.; Jarad, F.; Noor, M.N. Some estimates for generalized Riemann-Liouville fractional integrals of exponentially convex functions and their applications. Mathematics 2019, 7, 807. [Google Scholar] [CrossRef]
  14. Rahman, G.; Khan, A.; Abdeljawad, T.; Nisar, K.S. The Minkowski inequalities via generalized proportional fractional integral operators. Adv. Differ. Equ. 2019, 287, 1–14. [Google Scholar] [CrossRef]
  15. Sahoo, S.K.; Ahmad, H.; Tariq, M.; Kodamasingh, B.; Aydi, H.; De la Sen, M. Hermite-Hadamard type inequalities involving k-fractional operator for (h,m)-convex Functions. Symmetry 2021, 13, 1686. [Google Scholar] [CrossRef]
  16. Saleem, N.; Ishtiaq, U.; Guran, L.; Bota, M.F. On Graphical Fuzzy Metric Spaces with Application to Fractional Differential Equations. Fractal Fract. 2022, 6, 238. [Google Scholar] [CrossRef]
  17. Saleem, N.; Zhou, M.; Bashir, S.; Husnine, S.M. Some new generalizations of F-contraction type mappings that weaken certain conditions on Caputo fractional type differential equations. Aims Math. 2021, 6, 12718–12742. [Google Scholar] [CrossRef]
  18. Grüss, G. Uber das maximum des absoluten Betrages von 1 b a a b f ( x ) g ( x ) d x 1 ( b a ) 2 a b f ( x ) d x a b g ( x ) d x . Math. Z. 1935, 39, 215–226. [Google Scholar] [CrossRef]
  19. Kacar, E.; Kacar, Z.; Yildirim, H. Integral inequalities for Riemann-Liouville fractional integrals of a function with respect to another function. Iran. J. Math. Sci. Inform. 2018, 13, 1–13. [Google Scholar] [CrossRef]
  20. Rashid, S.; Noor, M.A.; Noor, K.I.; Safdar, F.; Chu, Y.M. Hermite-Hadamard inequalities for the class of convex functions on time scale. Mathematics 2019, 7, 956. [Google Scholar] [CrossRef]
  21. Okubo, S.; Isihara, A. Inequality for convex functions in quantum-statistical mechanics. Physica 1972, 59, 228–240. [Google Scholar] [CrossRef]
  22. Sudsutad, W.; Ntouyas, S.K.; Tariboon, J. Fractional integral inequalities via Hadamard’s fractional integral. Abstract. Appl. Anal. 2014, 11, 563096. [Google Scholar] [CrossRef]
  23. Mitrinović, D.S.; Vasić, P.M. History, variations and generalisations of the Cebysev inequality and the question of some priorities. Univ. Beograd. Publ. Elektrotehn. Fak. Ser. Mat. Fiz. 1974, 461/497, 1–30. Available online: http://www.jstor.org/stable/43667663 (accessed on 9 August 2022).
  24. Tariboon, J.; Ntouyas, S.K.; Sudsutad, W. Some new Riemann-Liouville fractional integral inequalities. Int. J. Math. Sci. 2014, 2014, 869434. [Google Scholar] [CrossRef]
  25. Balasubramanian, S. On the Grüss inequality for unital 2-positive linear maps. arXiv 2015, arXiv:1509.09040v3. [Google Scholar] [CrossRef]
  26. Izumino, S.; Pecaric, J.E. Some extensions of Grüssi’ inequality and its applications. Nihonkai Math. J. 2020, 13, 159–166. [Google Scholar]
  27. Butt, S.I.; Bakula, M.K.; Pecaric, D.; Pecaric, J. Jensen-Grüss inequality and its applications for the Zipf-Mandelbrot law. Math. Methods Appl. Sci. 2020, 44, 1664–1673. [Google Scholar] [CrossRef]
  28. Set, E.; Akdemir, A.O.; Ozata, F. Grüss type inequalities for fractional integral operator involving the extended generalized Mittag-Leffler function. Appl. Comput. Math. 2020, 19, 402–414. [Google Scholar]
  29. Butt, S.I.; Akdemir, A.O.; Nadeem, M.; Raza, M.A. Grüss type inequalities via generalized fractional operators. Math. Methods Appl. Sci. 2021, 44, 12559–12574. [Google Scholar] [CrossRef]
  30. Aljaaidi, T.A.; Pachpatte, D.B. Some Grüss-type inequalities using generalized Katugampola fractional integral. AIMS Math. 2020, 5, 1011–1024. [Google Scholar] [CrossRef]
  31. Sarikaya, M.Z. A Note on Grüss type inequalities on time scales. Dyn. Syst. Appl. 2008, 17, 663–666. [Google Scholar]
  32. Pachpatte, B.G. A note on Chebyshev-Grüss type inequalities for diferential functions. Tamsui Oxford J. Math. Sci. 2006, 22, 29–36. [Google Scholar]
  33. Rashid, S.; Jarad, F.; Noor, M.A.; Noor, K.I.; Baleanu, D. On Grüss inequalities within generalized K-fractional integrals. Adv. Diff. Equ. 2020, 203, 1–18. [Google Scholar] [CrossRef]
  34. Dahmani, Z.; Tabharit, L.; Taf, S. New generalisation of Grüss inequality using RiemannLiouville fractional integrals. Bull. Math. Anal. Appl. 2012, 2, 92–99. [Google Scholar]
  35. Chinchane, V.L.; Pachpatte, D.B. On some new Grüss-type inequality using Hadamard fractional integral operator. J. Fract. Calc. Appl. 2014, 5, 1–10. [Google Scholar]
  36. Sarikaya, M.Z. On an inequality of Grüss type via variant of Pompeiu’s mean value theorem. Pure Appl. Math. Lett. 2014, 2, 26–30. [Google Scholar]
  37. Kalla, S.L.; Rao, A. On Grüss type inequalities for a hypergeometric fractional integral. Le Matematiche 2011, LXVI, 57–64. [Google Scholar] [CrossRef]
  38. Mumcu, I.; Set, E. On new Grüss type inequalities for conformable fractional integrals. TWMS J. Appl. Eng. Math. 2019, 9, 1. [Google Scholar]
  39. Valdes, J.E.N.; Rodriguez, J.M.; Sigarreta, J.M. New Hermite-Hadamard type inequalities involving non-conformable integral operators. Symmetry 2019, 11, 1108. [Google Scholar] [CrossRef]
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Alsalami, O.M.; Sahoo, S.K.; Tariq, M.; Shaikh, A.A.; Cesarano, C.; Nonlaopon, K. Some New Fractional Integral Inequalities Pertaining to Generalized Fractional Integral Operator. Symmetry 2022, 14, 1691. https://doi.org/10.3390/sym14081691

AMA Style

Alsalami OM, Sahoo SK, Tariq M, Shaikh AA, Cesarano C, Nonlaopon K. Some New Fractional Integral Inequalities Pertaining to Generalized Fractional Integral Operator. Symmetry. 2022; 14(8):1691. https://doi.org/10.3390/sym14081691

Chicago/Turabian Style

Alsalami, Omar Mutab, Soubhagya Kumar Sahoo, Muhammad Tariq, Asif Ali Shaikh, Clemente Cesarano, and Kamsing Nonlaopon. 2022. "Some New Fractional Integral Inequalities Pertaining to Generalized Fractional Integral Operator" Symmetry 14, no. 8: 1691. https://doi.org/10.3390/sym14081691

APA Style

Alsalami, O. M., Sahoo, S. K., Tariq, M., Shaikh, A. A., Cesarano, C., & Nonlaopon, K. (2022). Some New Fractional Integral Inequalities Pertaining to Generalized Fractional Integral Operator. Symmetry, 14(8), 1691. https://doi.org/10.3390/sym14081691

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop