Bounds of a unified integral operator for (<em>s</em>,<em>m</em>)-convex functions and their consequences

Zitong He; Xiaolin Ma; Ghulam Farid; Absar Ul Haq; Kahkashan Mahreen; Zitong He; Xiaolin Ma; Ghulam Farid; Absar Ul Haq; Kahkashan Mahreen

doi:10.3934/math.2020353

AIMS Mathematics

2020, Volume 5, Issue 6: 5510-5520. doi: 10.3934/math.2020353

Previous Article Next Article

Research article

Bounds of a unified integral operator for (s,m)-convex functions and their consequences

1.
School of business administration, University of science and technology Liaoning, Anshan 114051, China
2.
Department of mathematics, COMSATS University Islamabad, Attock Campus, Pakistan
3.
Department of Basic Science and Humanities, University of Engineering and Technology, Lahore (Narowal Campus), Pakistan

Received: 25 January 2020 Accepted: 18 June 2020 Published: 28 June 2020
MSC : 26D10, 31A10, 26A33

The unified integral operator presented in Definition 4 produces several kinds of known fractional and conformable integral operators. The goal of this paper is to obtain bounds of this unified integral operator by using the definition of (s, m)-convexity. The resulting inequalities in specific cases represent the bounds of many known fractional and conformable fractional integral operators in a compact form.

Keywords:

Citation: Zitong He, Xiaolin Ma, Ghulam Farid, Absar Ul Haq, Kahkashan Mahreen. Bounds of a unified integral operator for (s,m)-convex functions and their consequences[J]. AIMS Mathematics, 2020, 5(6): 5510-5520. doi: 10.3934/math.2020353

Related Papers:

[1]	Ghulam Farid, Saira Bano Akbar, Shafiq Ur Rehman, Josip Pečarić . Boundedness of fractional integral operators containing Mittag-Leffler functions via (s,m)-convexity. AIMS Mathematics, 2020, 5(2): 966-978. doi: 10.3934/math.2020067
[2]	Yue Wang, Ghulam Farid, Babar Khan Bangash, Weiwei Wang . Generalized inequalities for integral operators via several kinds of convex functions. AIMS Mathematics, 2020, 5(5): 4624-4643. doi: 10.3934/math.2020297
[3]	Xinghua You, Ghulam Farid, Lakshmi Narayan Mishra, Kahkashan Mahreen, Saleem Ullah . Derivation of bounds of integral operators via convex functions. AIMS Mathematics, 2020, 5(5): 4781-4792. doi: 10.3934/math.2020306
[4]	Ghulam Farid, Maja Andrić, Maryam Saddiqa, Josip Pečarić, Chahn Yong Jung . Refinement and corrigendum of bounds of fractional integral operators containing Mittag-Leffler functions. AIMS Mathematics, 2020, 5(6): 7332-7349. doi: 10.3934/math.2020469
[5]	Wenfeng He, Ghulam Farid, Kahkashan Mahreen, Moquddsa Zahra, Nana Chen . On an integral and consequent fractional integral operators via generalized convexity. AIMS Mathematics, 2020, 5(6): 7632-7648. doi: 10.3934/math.2020488
[6]	Maryam Saddiqa, Ghulam Farid, Saleem Ullah, Chahn Yong Jung, Soo Hak Shim . On Bounds of fractional integral operators containing Mittag-Leffler functions for generalized exponentially convex functions. AIMS Mathematics, 2021, 6(6): 6454-6468. doi: 10.3934/math.2021379
[7]	D. L. Suthar, D. Baleanu, S. D. Purohit, F. Uçar . Certain k-fractional calculus operators and image formulas of k-Struve function. AIMS Mathematics, 2020, 5(3): 1706-1719. doi: 10.3934/math.2020115
[8]	M. Emin Özdemir, Saad I. Butt, Bahtiyar Bayraktar, Jamshed Nasir . Several integral inequalities for (α, s,m)-convex functions. AIMS Mathematics, 2020, 5(4): 3906-3921. doi: 10.3934/math.2020253
[9]	Hu Ge-JiLe, Saima Rashid, Muhammad Aslam Noor, Arshiya Suhail, Yu-Ming Chu . Some unified bounds for exponentially $tgs$-convex functions governed by conformable fractional operators. AIMS Mathematics, 2020, 5(6): 6108-6123. doi: 10.3934/math.2020392
[10]	Xiuzhi Yang, G. Farid, Waqas Nazeer, Muhammad Yussouf, Yu-Ming Chu, Chunfa Dong . Fractional generalized Hadamard and Fejér-Hadamard inequalities for m-convex functions. AIMS Mathematics, 2020, 5(6): 6325-6340. doi: 10.3934/math.2020407

Abstract

1. Introduction

First we give the definitions of generalized fractional integral operators which are special cases of the unified integral operators defined in (1.9), (1.10).

Definition 1.1. ^[1] Let $f:[a, b]\rightarrow\mathbb{R}$ be an integrable function. Also let $g$ be an increasing and positive function on $(a, b]$ , having a continuous derivative $g^{\prime}$ on $(a, b)$ . The left-sided and right-sided fractional integrals of a function $f$ with respect to another function $g$ on $[a, b]$ of order ${\mu}$ where $\Re(\mu) > 0$ are defined by:

$\begin{equation} _{g}^{\mu}I_{a^+}f(x) = \frac{1}{\Gamma({\mu})}\int_{a}^{x}(g(x)-g(t))^{{\mu}-1}g'(t)f(t)dt,\,\, x \gt a, \end{equation}$

(1.1)

$\begin{equation} _{g}^{\mu}I_{b^-}f(x) = \frac{1}{\Gamma({\mu})}\int_{x}^{b}(g(t)-g(x))^{{\mu}-1}g'(t)f(t)dt,\,\ x \lt b, \end{equation}$

(1.2)

where $\Gamma(.)$ is the gamma function.

Definition 1.2. ^[2] Let $f:[a, b]\rightarrow\mathbb{R}$ be an integrable function. Also let $g$ be an increasing and positive function on $(a, b]$ , having a continuous derivative $g^{\prime}$ on $(a, b)$ . The left-sided and right-sided fractional integrals of a function $f$ with respect to another function $g$ on $[a, b]$ of order ${\mu}$ where $\Re(\mu), k > 0$ are defined by:

$\begin{equation} ^{\mu}_{g}I^{k}_{a^+}f(x) = \frac{1}{k\Gamma_k({\mu})}\int_{a}^{x}(g(x)-g(t))^{\frac{\mu}{k}-1}g'(t)f(t)dt,\,\, x \gt a, \end{equation}$

(1.3)

$\begin{equation} ^{\mu}_{g}I^{k}_{b^-}f(x) = \frac{1}{k\Gamma_k({\mu})}\int_{x}^{b}(g(t)-g(x))^{\frac{\mu}{k}-1}g'(t)f(t)dt,\,\ x \lt b, \end{equation}$

(1.4)

where $\Gamma_{k}(.)$ is defined as follows ^[3]:

$\begin{equation} \Gamma_k(x) = \int_{0}^{\infty}t^{x-1}e^{-\frac{t^{k}}{k}} dt,\Re(x) \gt 0. \end{equation}$

(1.5)

A fractional integral operator containing an extended generalized Mittag-Leffler function in its kernel is defined as follows:

Definition 1.3. ^[4] Let $\omega, \mu, \alpha, l, \gamma, c\in \mathbb{C}$ , $\Re(\mu), \Re(\alpha), \Re(l) > 0$ , $\Re(c) > \Re(\gamma) > 0$ with $p\geq0$ , $\delta > 0$ and $0 < k\leq\delta+\Re(\mu)$ . Let $f\in L_{1}[a, b]$ and $x\in[a, b].$ Then the generalized fractional integral operators $\epsilon_{\mu, \alpha, l, \omega, a^{+}}^{\gamma, \delta, k, c}f$ and $\epsilon_{\mu, \alpha, l, \omega, b^{-}}^{\gamma, \delta, k, c}f$ are defined by:

$\begin{equation} \left( \epsilon_{\mu,\alpha,l,\omega,a^{+}}^{\gamma,\delta,k,c}f \right)(x;p) = \int_{a}^{x}(x-t)^{\alpha-1}E_{\mu,\alpha,l}^{\gamma,\delta,k,c}(\omega(x-t)^{\mu};p)f(t)dt, \end{equation}$

(1.6)

$\begin{equation} \left( \epsilon_{\mu,\alpha,l,\omega,b^{-}}^{\gamma,\delta,k,c}f \right)(x;p) = \int_{x}^{b}(t-x)^{\alpha-1}E_{\mu,\alpha,l}^{\gamma,\delta,k,c}(\omega(t-x)^{\mu};p)f(t)dt, \end{equation}$

(1.7)

where

$\begin{equation} E_{\mu,\alpha,l}^{\gamma,\delta,k,c}(t;p) = \sum\limits_{n = 0}^{\infty}\frac{\beta_{p}(\gamma+nk,c-\gamma)}{\beta(\gamma,c-\gamma)} \frac{(c)_{nk}}{\Gamma(\mu n +\alpha)} \frac{t^{n}}{(l)_{n \delta}} \end{equation}$

(1.8)

is the extended generalized Mittag-Leffler function and $(c)_{nk}$ is the Pochhammer symbol defined by $(c)_{nk} = \frac{\Gamma(c+nk)}{\Gamma(c)}$ .

Recently, a unified integral operator is defined as follows:

Definition 1.4. ^[5] Let $f, g:[a, b]\longrightarrow \mathbb{R}$ , $0 < a < b$ , be the functions such that $f$ be positive and $f\in L_{1}[a, b]$ , and $g$ be differentiable and strictly increasing. Also let $\frac{\phi}{x}$ be an increasing function on $[a, \infty)$ and $\alpha, l, \gamma, c$ $\in$ $\mathbb{C}$ , $p, \mu, \delta$ $\geq$ 0 and $0 < k\leq \delta + \mu$ . Then for $x\in[a, b]$ the left and right integral operators are defined by

$\begin{equation} (_gF_{\mu, \alpha, l, {a^+}}^{\phi, \gamma, \delta, k, c}f)(x,\omega;p) = \int_{a}^{x}K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)f(y)d(g(y)), \end{equation}$

(1.9)

$\begin{equation} (_gF_{\mu, \beta, l, {b^-}}^{\phi, \gamma, \delta, k, c}f)(x,\omega;p) = \int_{x}^{b}K_{y}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)f(y)d(g(y)), \end{equation}$

(1.10)

where the involved kernel is defined by

$\begin{equation} K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) = \dfrac{\phi(g(x)-g(y))}{g(x)-g(y)}E^{\gamma, \delta, k, c}_{\mu, \alpha, l}(\omega(g(x)-g(y))^{\mu}; p). \end{equation}$

(1.11)

For suitable settings of functions $\phi$ , $g$ and certain values of parameters included in Mittag-Leffler function, several recently defined known fractional and conformable fractional integrals studied in ^{[6,7,8,9,10,1,11,12,13,14,15,16,17]} can be reproduced, see [18,Remarks 6&7].

The aim of this study is to derive the bounds of all aforementioned integral operators in a unified form for $(s, m)$ -convex functions. These bounds will hold particularly for $m$ -convex, $s$ -convex and convex functions and for almost all fractional and conformable integrals defined in ^{[6,7,8,9,10,1,11,12,13,14,15,16,17]}.

Definition 1.5. ^[19] A function $f:[0, b]\rightarrow \mathbb{R}, \, b > 0$ is said to be $(s, m)$ -convex, where $(s, m)\in[0, 1]^{2}$ if

$\begin{equation} f(tx+m(1-t)y)\leq t^{s}f(x)+m(1-t)^{s}f(y) \end{equation}$

(1.12)

holds for all $x, y\in[0, b]\, \, and\, \, t\in[0, 1].$

Remark 1. 1. If we take $(s, m)$ = $(1, m)$ , then (1.12) gives the definition of $m$ -convex function.

2. If we take $(s, m)$ = $(1, 1)$ , then (1.12) gives the definition of convex function.

3. If we take $(s, m)$ = $(1, 0)$ , then (1.12) gives the definition of star-shaped function.

2. Properties of the kernel $K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)$

P1: Let $g$ and $\frac{\phi}{x}$ be increasing functions. Then for $x < t < y$ , $x, y\in[a, b]$ the kernel $K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)$ satisfies the following inequality:

$\begin{equation} K_{t}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(t)\leq K_{y}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(t). \end{equation}$

(2.1)

This can be obtained from the following two straightforward inequalities:

$\begin{equation} \dfrac{\phi(g(t)-g(x))}{g(t)-g(x)}g'(t)\leq\dfrac{\phi(g(y)-g(x))}{g(y)-g(x)}g'(t), \end{equation}$

(2.2)

$\begin{equation} E^{\gamma, \delta, k, c}_{\mu, \alpha, l}(\omega(g(t)-g(x))^{\mu}; p)\leq E^{\gamma, \delta, k, c}_{\mu, \alpha, l}(\omega(g(y)-g(x))^{\mu}; p). \end{equation}$

(2.3)

The reverse of inequality (1.9) holds when $g$ and $\frac{\phi}{x}$ are decreasing.

P2: Let $g$ and $\frac{\phi}{x}$ be increasing functions. If $\phi(0) = \phi'(0) = 0$ , then for $x, y\in[a, b], \, x < y$ ,

$K_{y}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)\geq0$ .

P3: For $p, q \in \mathbb{R}$ ,

$K_{y}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;p\phi_1+q\phi_2) = p K_{y}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi_1)+q K_{y}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi_2).$

The upcoming section contains the results which deal with the bounds of several integral operators in a compact form by utilizing $(s, m)$ -convex functions. A version of the Hadamard inequality in a compact form is presented, also a modulus inequality is given for differentiable function $f$ such that $|f'|$ is $(s, m)$ -convex function.

3. Main results

In this section first we will state the main results. The following result provides upper bound of unified integral operators.

Theorem 3.1. Let $f:[a, b]\longrightarrow \mathbb{R}$ , $0\leq a < b$ be a positive integrable $(s, m)$ -convex function, $m\in(0, 1]$ . Let $g:[a, b]\longrightarrow \mathbb{R}$ be differentiable and strictly increasing function, also let $\frac{\phi}{x}$ be an increasing function on $[a, b]$ . If $\alpha, \beta, l, \gamma, c \in\mathbb{C}$ , $p, \mu \geq 0, \delta \geq 0$ and $0 < k\leq \delta + \mu$ , then for $x\in(a, b)$ the following inequality holds for unified integral operators:

$\begin{align} &\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\right)(x,\omega; p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\right)(x,\omega; p)\\ &\leq K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\left(mf\left(\frac{x}{m}\right)g(x)-f(a)g(a)-\dfrac{\Gamma(s+1)}{(x-a)^{s}}\left(mf\left(\frac{x}{m}\right)\, ^{s}I_{x^{-}}g(a)-f(a)\, ^{s}I_{a^{+}}g(x)\right)\right)\\ &+K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)\left(f(b)g(b)-mf\left(\frac{x}{m}\right)g(x)-\dfrac{\Gamma(s+1)}{(b-x)^{s}}\left(f(b)\, ^{s}I_{b^{-}}g(x)-mf\left(\frac{x}{m}\right)\, ^{s}I_{x^{+}}g(b)\right)\right). \end{align}$

(3.1)

Lemma 3.2. ^[20] Let $f: [0, \infty] \longrightarrow \mathbb{R}$ , be an $(s, m)$ -convex function, $m\in(0, 1]$ . If $f(x) = f(\frac{a+b-x}{m})$ , then the following inequality holds:

$\begin{equation} f\left(\frac{a+b}{2}\right)\leq \frac{1}{2^{s}}(1+m)f(x)\,\,\,\,\,\,\,x\in[a,b]. \end{equation}$

(3.2)

The following result provides generalized Hadamard inequality for $(s, m)$ -convex functions.

Theorem 3.3. Under the assumptions of Theorem 3.1, in addition if $f(x) = f\left(\dfrac{a+b-x}{m}\right)$ , $m\in(0, 1]$ , then the following inequality holds:

$\begin{align} &\dfrac{2^{s}}{\left(1+m\right)}f\left(\dfrac{a+b}{2}\right)\left(\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}} 1\right)(a,\omega;p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}} 1\right)(b,\omega;p)\right)\\ &\leq \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}} f\right)(a,\omega;p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}} f\right)(b,\omega;p)\\ & \leq \left( K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)+K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\right)\left(f(b)g(b)-mf\left(\dfrac{a}{m}\right)g(a)\right.\\ &\left.-\dfrac{\Gamma(s+1)}{(b-a)^{s}}\left(f(b)\, ^{s}I_{b^{-}}g(a)-mf\left(\dfrac{a}{m}\right)\, ^{s}I_{a^{+}}g(b)\right)\right). \end{align}$

(3.3)

Theorem 3.4. Let $f:[a, b]\longrightarrow \mathbb{R}$ , $0\leq a < b$ be a differentiable function. If $|f'|$ is $(s, m)$ -convex, $m\in(0, 1]$ and $g:[a, b]\longrightarrow \mathbb{R}$ be differentiable and strictly increasing function, also let $\frac{\phi}{x}$ be an increasing function on $[a, b]$ . If $\alpha, \beta, l, \gamma, c\in\mathbb{C}$ , $p, \mu \geq 0$ , $\delta \geq 0$ and $0 < k\leq \delta + \mu$ , then for $x\in(a, b)$ we have

$\begin{align} &\left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\ast g\right)(x,\omega; p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\ast g\right)(x,\omega; p)\right| \\&\leq K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\left(m\left|f'\left(\frac{x}{m}\right)\right|g(x)-|f'(a)|g(a)-\dfrac{\Gamma(s+1)}{(x-a)^{s}}\left(m\left|f'\left(\frac{x}{m}\right)\right|\, ^{s}I_{x^{-}}g(a)-|f'(a)|\, ^{s}I_{a^{+}}g(x)\right)\right)\\ \nonumber&+K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)\left(|f'(b)|g(b)-m\left|f'\left(\frac{x}{m}\right)\right|g(x)-\dfrac{\Gamma(s+1)}{(b-x)^{s}}\left(|f'(b)|\, ^{s}I_{b^{-}}g(x)-m\left|f'\left(\frac{x}{m}\right)\right|\, ^{s}I_{x^{+}}g(b)\right)\right),\nonumber \end{align}$

(3.4)

where

$\begin{equation*} \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\ast g\right)(x,\omega; p): = \int_{a}^{x}K_{x}^{t}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)f'(t)d(g(t)), \end{equation*}$

$\begin{equation*} \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\ast g\right)(x,\omega; p): = \int_{x}^{b}K_{t}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)f'(t)d(g(t)). \end{equation*}$

4. Proofs of main results

In this section we give the proves of the results stated in aforementioned section.

Proof of Theorem 3.1. By $(\bf{P_1})$ , the following inequalities hold:

$\begin{equation} K_{x}^{t}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(t)\leq K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(t),\,\ a \lt t \lt x, \end{equation}$

(4.1)

$\begin{equation} K_{t}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(t)\leq K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)g'(t),\,\ x \lt t \lt b. \end{equation}$

(4.2)

For $(s, m)$ -convex function the following inequalities hold:

$\begin{equation} f(t)\leq \bigg(\dfrac{x-t}{x-a}\bigg)^{s}f(a)+m\bigg(\dfrac{t-a}{x-a}\bigg)^{s}f\bigg(\frac{x}{m}\bigg),\,\ a \lt t \lt x, \end{equation}$

(4.3)

$\begin{equation} f(t)\leq \bigg(\dfrac{t-x}{b-x}\bigg)^{s}f(b)+m\bigg(\dfrac{b-t}{b-x}\bigg)^{s}f\bigg(\frac{x}{m}\bigg),\,\ x \lt t \lt b. \end{equation}$

(4.4)

From (4.1) and (4.3), the following integral inequality holds true:

$\begin{align} &\int_{a}^{x} K_{x}^{t}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) f(t)d(g(t))\leq f(a)K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\\ &\times\int_{a}^{x}\left(\dfrac{x-t}{x-a}\right)^{s} d(g(t))+mf\left(\dfrac{x}{m}\right)K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\int_{a}^{x}\left(\dfrac{t-a}{x-a}\right)^{s} d(g(t)). \end{align}$

(4.5)

Further the aforementioned inequality takes the form which involves Riemann-Liouville fractional integrals in the right hand side, provides the upper bound of unified left sided integral operator (1.1) as follows:

$\begin{align} &\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\right)(x,\omega; p) \leq K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\left(mf\left(\frac{x}{m}\right)g(x)-f(a)g(a)\right.\\ &\left.-\dfrac{\Gamma(s+1)}{(x-a)^{s}}\left(mf\left(\frac{x}{m}\right)\, ^{s}I_{x^{-}}g(a)-f(a)\, ^{s}I_{a^{+}}g(x)\right)\right). \end{align}$

(4.6)

On the other hand from (4.2) and (4.4), the following integral inequality holds true:

$\begin{align} &\int_{x}^{b} K_{t}^{x}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) f(t)d(g(t))\leq f(b)K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)\\ &\times\int_{x}^{b}\left(\dfrac{t-x}{b-x}\right)^{s} d(g(t))+mf\left(\dfrac{x}{m}\right)K_{x}^{b}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\int_{x}^{b}\left(\dfrac{b-t}{b-x}\right)^{s} d(g(t)). \end{align}$

(4.7)

Further the aforementioned inequality takes the form which involves Riemann-Liouville fractional integrals in the right hand side, provides the upper bound of unified right sided integral operator (1.2) as follows:

$\begin{align} &\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\right)(x,\omega; p) \leq K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)\left(f(b)g(b)-mf\left(\frac{x}{m}\right)g(x)\right.\\ &\left.-\dfrac{\Gamma(s+1)}{(b-x)^{s}}\left(f(b)\, ^{s}I_{b^{-}}g(x)-mf\left(\frac{x}{m}\right)\, ^{s}I_{x^{+}}g(b)\right)\right). \end{align}$

(4.8)

By adding (4.6) and (4.8), (3.1) can be obtained.

Remark 2. (ⅰ) If we consider $(s, m)$ = (1, 1) in (3.1), [18,Theorem 1] is obtained.

(ⅱ) If we consider $p = \omega = 0$ in (3.1), [20,Theorem 1] is obtained.

(ⅲ) If we consider $\phi(t) = \Gamma(\alpha)t^{\alpha}$ , $p = \omega = 0$ and $(s, m)$ = (1, 1) in (3.1), [21,Theorem 1] is obtained.

(ⅳ) If we consider $\alpha = \beta$ in the result of (ⅲ), then [21,Corollary 1] is obtained.

(ⅴ) If we consider $\phi(t) = t^{\alpha}$ , $g(x) = x$ and $m = 1$ in (3.1), then [22,Theorem 2.1] is obtained.

(ⅵ) If we consider $\alpha = \beta$ in the result of (v), then [22,Corollary 2.1] is obtained.

(ⅶ) If we consider $\phi(t) = \frac{\Gamma (\alpha) t^\frac{\alpha}{k}}{k\Gamma_k(\alpha)}$ , $(s, m)$ = (1, 1), $g(x) = x$ and $p = \omega = 0$ in (3.1), then [23,Theorem 1] can be obtained.

(ⅷ) If we consider $\alpha = \beta$ in the result of (ⅶ), then [23,Corollary 1] can be obtained.

(ⅸ) If we consider $\phi(t) = \Gamma(\alpha)t^{\alpha}$ , $g(x) = x$ and $p = \omega = 0$ and $(s, m)$ = (1, 1) in (3.1), then [24,Theorem 1] is obtained.

(ⅹ) If we consider $\alpha = \beta$ in the result of (ⅸ), then [24,Corollary 1] can be obtained.

(ⅹⅰ) If we consider $\alpha = \beta = 1$ and $x = a\, \ or \, \ x = b$ in the result of (x), then [24,Corollary 2] can be obtained.

(ⅹⅱ) If we consider $\alpha = \beta = 1$ and $x = \dfrac{a+b}{2}$ in the result of (ⅹ), then [24,Corollary 3] can be obtained.

Proof of Theorem 3.3. By $(\bf{P_1})$ , the following inequalities hold:

$\begin{equation} K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(x)\leq K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(x),\,\ a \lt x \lt b, \end{equation}$

(4.9)

$\begin{equation} K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)g'(x)\leq K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)g'(x)\,\ a \lt x \lt b. \end{equation}$

(4.10)

For $(s, m)$ -convex function $f$ , the following inequality holds:

$\begin{equation} f(x)\leq \bigg(\dfrac{x-a}{b-a}\bigg)^{s}f(b)+m\bigg(\dfrac{b-x}{b-a}\bigg)^{s}f\bigg(\frac{a}{m}\bigg),\,\,\ a \lt x \lt b. \end{equation}$

(4.11)

From (4.9) and (4.11), the following integral inequality holds true:

$\begin{align*} &\int_{a}^{b} K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)f(x)d(g(x))\\ \nonumber &\leq mf\left(\dfrac{a}{m}\right)K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\int_{a}^{b}\left(\dfrac{b-x}{b-a}\right)^{s}d(g(x))+f(b)K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\int_{a}^{b}\left(\dfrac{x-a}{b-a}\right)^{s} d(g(x)). \end{align*}$

$\begin{align} &\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}}f\right)(a,\omega; p) \leq K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) \bigg(f(b)g(b)-mf\bigg(\frac{a}{m}\bigg)g(a)\\ &-\dfrac{\Gamma(s+1)}{(b-a)^{s}}\bigg(f(b)\, ^{s}I_{b^{-}}g(a)-mf\bigg(\frac{a}{m}\bigg)\, ^{s}I_{a^{+}}g(b)\bigg)\bigg). \end{align}$

(4.12)

On the other hand from (4.9) and (4.11), the following inequality holds which involves Riemann-Liouville fractional integrals on the right hand side and estimates of the integral operator (1.2):

$\begin{align} &\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}}f\right)(b,\omega; p) \leq K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) \bigg(f(b)g(b)-mf\bigg(\frac{a}{m}\bigg)g(a)\\ &-\dfrac{\Gamma(s+1)}{(b-a)^{s}}\bigg(f(b)\, ^{s}I_{b^{-}}g(a)-mf\bigg(\frac{a}{m}\bigg)\, ^{s}I_{a^{+}}g(b)\bigg)\bigg). \end{align}$

(4.13)

By adding (4.12) and (4.13), following inequality can be obtained:

$\begin{align} &\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}}f\right)(a,\omega; p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}}f\right)(b,\omega; p)\\ & \leq \left(K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)+K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\right) \bigg(f(b)g(b)-mf\bigg(\frac{a}{m}\bigg)g(a)\\ &-\dfrac{\Gamma(\alpha+1)}{(b-a)^{s}}\bigg(f(b)\, ^{s}I_{b^{-}}g(b)-mf\bigg(\frac{a}{m}\bigg)\, ^{s}I_{a^{+}}g(b)\bigg)\bigg). \end{align}$

(4.14)

Multiplying both sides of (3.2) by $K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)g'(x)$ , and integrating over $[a, b]$ we have

$\begin{equation*} f\left(\dfrac{a+b}{2}\right)\int_{a}^{b} K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)d(g(x))\leq \left(\dfrac{1}{2^{s}}\right)\left(1+m\right)\int_{a}^{b} K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)f(x)d(g(x)). \end{equation*}$

From Definition 1.4, the following inequality is obtained:

$\begin{equation} f\left(\dfrac{a+b}{2}\right)\dfrac{2^{s}}{(1+m)}\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}} 1\right)(a,\omega;p)\leq \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}} f\right)(a,\omega;p). \end{equation}$

(4.15)

Similarly multiplying both sides of (3.2) by $K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l}, g;\phi)g'(x)$ , and integrating over $[a, b]$ we have

$\begin{equation} f\left(\dfrac{a+b}{2}\right)\dfrac{2^{s}}{(1+m)}\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}} 1\right)(b,\omega;p)\leq \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}} f\right)(b,\omega;p). \end{equation}$

(4.16)

By adding (4.15) and (4.16) the following inequality is obtained:

$\begin{align} &f\left(\dfrac{a+b}{2}\right)\dfrac{2^{s}}{(1+m)}\left(\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}} 1\right)(b,\omega;p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}} 1\right)(a,\omega;p)\right)\\ &\leq \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {a^+}} f\right)(b,\omega;p)+\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {b^-}} f\right)(a,\omega;p). \end{align}$

(4.17)

Using (4.14) and (4.17), inequality (3.3) can be obtained, this completes the proof.

Remark 3. (ⅰ) If we consider $(s, m)$ = (1, 1) in (3.3), [18,Theorem 2] is obtained.

(ⅱ) If we consider $p = \omega = 0$ in (3.3), [20,Theorem 3] is obtained.

(ⅲ) If we consider $\phi(t) = \Gamma(\alpha)t^{\alpha+1}$ , $p = \omega = 0$ and $(s, m)$ = (1, 1) in (3.3), [21,Theorem 3] is obtained.

(ⅳ) If we consider $\alpha = \beta$ in the result of (iii), then [21,Corollary 3] is obtained.

(ⅴ) If we consider $\phi(t) = t^{\alpha+1}$ , $g(x) = x$ and $m = 1$ in (3.3), then [22,Theorem 2.4] is obtained.

(ⅵ) If we consider $\alpha = \beta$ in the result of (v), then [22,Corollary 2.6] is obtained.

(ⅶ) If we consider $\phi(t) = \Gamma (\alpha) t^{\frac{\alpha}{k}+1}$ , $(s, m)$ = (1, 1), $g(x) = x$ and $p = \omega = 0$ in (3.3), then [23,Theorem 3] can be obtained.

(ⅷ) If we consider $\alpha = \beta$ in the result of (ⅶ), then [23,Corollary 6] can be obtained.

(ⅸ) If we consider $\phi(t) = \Gamma(\alpha)t^{\alpha+1}$ , $p = \omega = 0$ , $(s, m) = 1$ and $g(x) = x$ in (3.3), [24,Theorem 3] can be obtained.

(ⅹ) If we consider $\alpha = \beta$ in the result of (ⅸ), [24,Corrolary 6] can be obtained.

Proof of Theorem 3.4. For $(s, m)$ -convex function the following inequalities hold:

$\begin{equation} |f'(t)|\leq\bigg(\dfrac{x-t}{x-a}\bigg)^{s}|f'(a)|+m\bigg(\dfrac{t-a}{x-a}\bigg)^{s}\left|f'\bigg(\frac{x}{m}\bigg)\right|,\,\ a \lt t \lt x, \end{equation}$

(4.18)

$\begin{equation} |f'(t)|\leq\bigg(\dfrac{t-x}{b-x}\bigg)^{s}|f'(b)|+m\bigg(\dfrac{b-t}{b-x}\bigg)^{s}\left|f'\bigg(\frac{x}{m}\bigg)\right|,\,\ x \lt t \lt b. \end{equation}$

(4.19)

From (4.1) and (4.18), the following inequality is obtained:

$\begin{align} &\left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}(f\ast g)\right)(x,\omega; p)\right| \leq\dfrac{K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)}{(x-a)^{s}}\\ &\times\left((x-a)^{s}\left(m\left|f'\left(\frac{x}{m}\right)\right|g(x)-|f'(a)|g(a)\right)-\Gamma(s+1)\left(m\left|f'\left(\frac{x}{m}\right)\right|\, ^{s}I_{x^{-}}g(a)-|f'(a)|\, ^{s}I_{a^{+}}g(x)\right)\right). \end{align}$

(4.20)

Similarly, from (4.2) and (4.19), the following inequality is obtained:

$\begin{align} &\left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}(f\ast g)\right)(x,\omega; p)\right| \leq\dfrac{K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)}{(b-x)^{s}}\\ &\times\left((b-x)^{s}\left(|f'(b)|g(b)-mf'\left|\left(\frac{x}{m}\right)\right| g(x)\right)-\Gamma(s+1)\left(|f'(b)|\, ^{s}I_{b^{-}}g(x)-mf'\left|\left(\frac{x}{m}\right)\right|\, ^{s}I_{x^{+}}g(b)\right)\right). \end{align}$

(4.21)

By adding (4.20) and (4.21), inequality (3.4) can be achieved.

Remark 4. (ⅰ) If we consider $(s, m)$ = (1, 1) in (3.4), then [18,Theorem 3] is obtained.

(ⅱ) If we consider $p = \omega = 0$ in (3.4), then [20,Theorem 2] is obtained.

(ⅲ) If we consider $\phi(t) = \Gamma(\alpha)t^{\alpha+1}$ , $p = \omega = 0$ and $(s, m)$ = (1, 1) in (3.4), then [21,Theorem 2] is obtained.

(ⅳ) If we consider $\alpha = \beta$ in the result of (iii), then [21,Corollary 2] is obtained.

(ⅴ) If we consider $\phi(t) = t^{\alpha}$ , $g(x) = x$ and $m = 1$ in (3.4), then [22,Theorem 2.3] is obtained.

(ⅵ) If we consider $\alpha = \beta$ in the result of (v), then [22,Corollary 2.5] is obtained.

(ⅶ) If we consider $\phi(t) = \Gamma (\alpha) t^{\frac{\alpha}{k}+1}$ , $(s, m)$ = (1, 1), $g(x) = x$ and $p = \omega = 0$ in (3.4), then [23,Theorem 2] can be obtained.

(ⅷ) If we consider $\alpha = \beta$ in the result of (ⅶ), then [23,Corollary 4] can be obtained.

(ⅸ) If we consider $\alpha = \beta = k = 1$ and $x = \dfrac{a+b}{2}$ , in the result of (ⅷ), then [23,Corollary 5] can be obtained.

(ⅹ) If we consider $\phi(t) = \Gamma(\alpha)t^{\alpha+1}$ , $g(x) = x$ and $p = \omega = 0$ and $(s, m)$ = (1, 1) in (3.4), then [24,Theorem 2] is obtained.

(ⅹⅰ) If we consider $\alpha = \beta$ in the result of (x), then [24,Corollary 5] can be obtained.

5. Boundedness and continuity

In this section, we have established boundedness and continuity of unified integral operators for $m$ -convex and convex functions.

Theorem 5.1. Under the assumptions of Theorem 1, the following inequality holds for $m$ -convex functions:

(5.1)

Proof. If we put $s = 1$ in (4.5), we have

$\begin{align} &\int_{a}^{x} K_{x}^{t}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) f(t)d(g(t))\leq f(a)K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\\ &\times\int_{a}^{x}\left(\dfrac{x-t}{x-a}\right) d(g(t))+mf\left(\dfrac{x}{m}\right)K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)\int_{a}^{x}\left(\dfrac{t-a}{x-a}\right) d(g(t)). \end{align}$

(5.2)

Further from simplification of (5.2), the following inequality holds:

$\begin{align} \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\right)(x,\omega; p)\leq K_{x}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi)(g(x)-g(a))\left(mf\left(\dfrac{x}{m}\right)+f(a)\right). \end{align}$

(5.3)

Similarly from (4.8), the following inequality holds:

$\begin{equation} \left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\right)(x,\omega; p)\leq K_{b}^{x}(E^{\gamma, \delta, k, c}_{\mu, \beta, l},g;\phi)(g(b)-g(x))\left(mf\left(\dfrac{x}{m}\right)+f(b)\right). \end{equation}$

(5.4)

From (5.3) and (5.4), (5.1) can be obtained.

Theorem 5.2. With assumptions of Theorem 4, if $f\in L_{\infty}[a, b]$ , then unified integral operators for $m$ -convex functions are bounded and continuous.

Proof. From (5.3) we have

$\begin{equation*} \label{2.13-} \left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\right)(x,\omega; p)\right| \leq K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l},g;\phi) (g(b)-g(a))(m+1)\|f\|_{\infty}, \end{equation*}$

which further gives

$\begin{equation*} \label{2.15} \left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\right)(x,\omega; p)\right| \leq K \|f\|_{\infty}, \end{equation*}$

where $K = (g(b)-g(a))(m+1)K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)$ .

Similarly, from (5.4) the following inequality holds:

$\begin{equation*} \label{2.16} \left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\right)(x,\omega; p)\right| \leq K \|f\|_{\infty}. \end{equation*}$

Hence the boundedness is followed, further from linearity the continuity of (1.9) and (1.10) is obtained.

Corollary 1. If we take $m = 1$ in Theorem 5, then unified integral operators for convex functions are bounded and continuous and following inequalities hold:

$\begin{equation*} \label{2.115} \left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \alpha, l, {a^+}}f\right)(x,\omega; p)\right| \leq K \|f\|_{\infty}, \end{equation*}$

$\begin{equation*} \label{2.116} \left|\left(_gF^{\phi, \gamma, \delta, k, c}_{\mu, \beta, l, {b^-}}f\right)(x,\omega; p)\right| \leq K \|f\|_{\infty}, \end{equation*}$

where $K = 2(g(b)-g(a))K_{b}^{a}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)$ .

6. Conclusions

This paper has explored bounds of a unified integral operator for $(s, m)$ -convex functions. These bounds are obtained in a compact form which have further interesting consequences with respect to fractional and conformable integrals for convex, $m$ -convex and $s$ -convex functions. Furthermore by applying Theorems 3.1, 3.3 and 3.4 several associated results can be derived for different kinds of fractional integral operators of convex, $m$ -convex and $s$ -convex functions.

Acknowledgments

This work was sponsored in part by Social Science Planning Fund of Liaoning Province of China(L15AJL001, L16BJY011, L18AJY001), Scientific Research Fund of The Educational Department of Liaoning Province(2017LNZD07, 2016FRZD03), Scientific Research Fund of University of science and technology Liaoning(2016RC01, 2016FR01)

Conflict of interest

The authors declare that no competing interests exist.

References

[1]	A. A. Kilbas, H. M. Srivastava, J. J Trujillo, Theory and applications of fractional differential equations, North-Holland Mathematics Studies, 204, Elsevier, New York-London, 2006.
[2]	Y. C. Kwun, G. Farid, W. Nazeer, et al. Generalized Riemann-Liouville k-fractional integrals associated with Ostrowski type inequalities and error bounds of Hadamard inequalities, IEEE Access, 6 (2018), 64946-64953. doi: 10.1109/ACCESS.2018.2878266
[3]	S. Mubeen, A. Rehman, A note on k-Gamma function and Pochhammer k-symbol, J. Inform. Math. Sci., 6 (2014), 93-107.
[4]	M. Andrić, G. Farid, J. Pečarić, A further extension of Mittag-Leffler function, Fract. Calc. Appl. Anal., 21 (2018), 1377-1395. doi: 10.1515/fca-2018-0072
[5]	S. G. Farid, A unified integral operator and its consequences, Open J. Math. Anal., 4 (2020), 1-7. doi: 10.30538/psrp-oma2020.0047
[6]	H. Chen, U. N. Katugampola, Hermite-Hadamard and Hermite-Hadamard-Fejér type inequalities for generalized fractional integrals, J. Math. Anal. Appl., 446 (2017), 1274-1291. doi: 10.1016/j.jmaa.2016.09.018
[7]	S. S. Dragomir, Inequalities of Jensens type for generalized k-g-fractional integrals of functions for which the composite f ◦ g^-1 is convex, Fract. Differ. Calc., 1 (2018), 127-150.
[8]	S. Habib, S. Mubeen, M. N. Naeem, Chebyshev type integral inequalities for generalized kfractional conformable integrals, J. Inequal. Spec. Funct., 9 (2018), 53-65.
[9]	F. Jarad, E. Ugurlu, T. Abdeljawad, et al. On a new class of fractional operators, Adv. Differ. Equ., 2017 (2017), 247.
[10]	T. U. Khan, M. A. Khan, Generalized conformable fractional operators, J. Comput. Appl. Math., 346 (2019), 378-389. doi: 10.1016/j.cam.2018.07.018
[11]	S. Mubeen, G. M. Habibullah, k-fractional integrals and applications, Int. J. Contemp. Math., 7 (2012), 89-94.
[12]	T. R. Parbhakar, A singular integral equation with a generalized Mittag-Leffler function in the kernel, Yokohama Math. J., 19 (1971), 7-15.
[13]	G. Rahman, D. Baleanu, M. A. Qurashi, et al. The extended Mittag-Leffler function via fractional calculus, J. Nonlinear Sci. Appl., 10 (2017), 4244-4253. doi: 10.22436/jnsa.010.08.19
[14]	T. O. Salim, A. W. Faraj, A generalization of Mittag-Leffler function and integral operator associated with integral calculus, J. Fract. Calc. Appl., 3 (2012), 1-13. doi: 10.1142/9789814355216_0001
[15]	M. Z. Sarikaya, M. Dahmani, M. E. Kiris, et al. (k, s)-Riemann-Liouville fractional integral and applications, Hacet. J. Math. Stat., 45 (2016), 77-89.
[16]	H. M. Srivastava, Z. Tomovski, Fractional calculus with an integral operator containing generalized Mittag-Leffler function in the kernel, Appl. Math. Comput., 211 (2009), 198-210.
[17]	T. Tunc, H. Budak, F. Usta, et al. On new generalized fractional integral operators and related fractional inequalities, ResearchGate, 2017. Available from: https://www.researchgate.net/publication/313650587.
[18]	Y. C. Kwun, G. Farid, S. Ullah, et al. Inequalities for a unified integral operator and associated results in fractional calculus, IEEE Access, 7 (2019), 126283-126292. doi: 10.1109/ACCESS.2019.2939166
[19]	N. Eftekhari, Some remarks on (s, m)-convexity in the second sense, J. Math. Inequal., 8 (2014), 489-495.
[20]	Y. C. Kwun, G. Farid, S. M. Kang, et al. Derivation of bounds of several kinds ofoperators via (s, m)-convexity, Adv. Differ. Equ., 2020 (2020), 1-14. doi: 10.1186/s13662-019-2438-0
[21]	G. Farid, W. Nazeer, M. S. Saleem, et al. Bounds of Riemann-Liouville fractional integrals in general form via convex functions and their applications, Mathematics, 6 (2018), 248.
[22]	L. Chen, G. Farid, S. I. Butt, et al. Boundedness of fractional integral operators containing MittagLeffler functions, Turkish J. Inequal., 4 (2020), 14-24.
[23]	G. Farid, Estimation of Riemann-Liouville k-fractional integrals via convex functions, Acta et Commentat. Univ. Tartuensis de Math., 23 (2019), 71-78.
[24]	G. Farid, Some Riemann-Liouville fractional integral for inequalities for convex functions, J. Anal., 27 (2019), 1095-1102. doi: 10.1007/s41478-018-0079-4

This article has been cited by:

1.	Ghulam Farid, Yu-Ming Chu, Maja Andrić, Chahn Yong Jung, Josip Pečarić, Shin Min Kang, Xinguang Zhang, Refinements of Some Integral Inequalities for s , m -Convex Functions, 2020, 2020, 1563-5147, 1, 10.1155/2020/8878342
2.	Zhongyi Zhang, Ghulam Farid, Kahkashan Mahreen, Fu-Dong Ge, Inequalities for Unified Integral Operators via Strongly α , h ‐ m -Convexity, 2021, 2021, 2314-8888, 1, 10.1155/2021/6675826
3.	Timing Yu, Ghulam Farid, Kahkashan Mahreen, Chahn Yong Jung, Soo Hak Shim, Ghulam Mustafa, On Generalized Strongly Convex Functions and Unified Integral Operators, 2021, 2021, 1563-5147, 1, 10.1155/2021/6695781
4.	Yonghong Liu, Ghulam Farid, Dina Abuzaid, Hafsa Yasmeen, On boundedness of fractional integral operators via several kinds of convex functions, 2022, 7, 2473-6988, 19167, 10.3934/math.20221052
5.	Wengui Yang, Certain New Chebyshev and Grüss-Type Inequalities for Unified Fractional Integral Operators via an Extended Generalized Mittag-Leffler Function, 2022, 6, 2504-3110, 182, 10.3390/fractalfract6040182
6.	WENGUI YANG, CERTAIN NEW WEIGHTED YOUNG- AND PÓLYA–SZEGÖ-TYPE INEQUALITIES FOR UNIFIED FRACTIONAL INTEGRAL OPERATORS VIA AN EXTENDED GENERALIZED MITTAG-LEFFLER FUNCTION WITH APPLICATIONS, 2022, 30, 0218-348X, 10.1142/S0218348X22501067

Reader Comments

Your name:*

Email:*
© 2020 the Author(s), licensee AIMS Press. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/4.0)

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

AIMS Mathematics

1.8 3.4

Metrics

Article views(4269) PDF downloads(248) Cited by(6)

Preview PDF

Download XML

Export Citation

Article outline

Show full outline

AIMS Mathematics

Bounds of a unified integral operator for (s,m)-convex functions and their consequences

Related Papers:

Abstract

1. Introduction

2. Properties of the kernel $K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)$

3. Main results

4. Proofs of main results

5. Boundedness and continuity

6. Conclusions

Acknowledgments

Conflict of interest

References

This article has been cited by:

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Other Articles By Authors

Catalog

AIMS Mathematics

Bounds of a unified integral operator for (s,m)-convex functions and their consequences

Related Papers:

Abstract

1. Introduction

2. Properties of the kernel Kyx(Eγ,δ,k,cμ,α,l,g;ϕ) K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)

3. Main results

4. Proofs of main results

5. Boundedness and continuity

6. Conclusions

Acknowledgments

Conflict of interest

References

This article has been cited by:

Reader Comments

通讯作者: 陈斌, bchen63@163.com

Metrics

Other Articles By Authors

Related pages

Tools

Export File

Citation

Format

Content

Catalog

2. Properties of the kernel $K_{x}^{y}(E^{\gamma, \delta, k, c}_{\mu, \alpha, l}, g;\phi)$