On Some New Maclaurin’s Type Inequalities for Convex Functions in q-Calculus

Sitthiwirattham, Thanin; Ali, Muhammad Aamir; Budak, Hüseyin

doi:10.3390/fractalfract7080572

Open AccessArticle

On Some New Maclaurin’s Type Inequalities for Convex Functions in q-Calculus

by

Thanin Sitthiwirattham

^1,2

,

Muhammad Aamir Ali

³

and

Hüseyin Budak

^4,*

¹

Mathematics Department, Faculty of Science and Technology, Suan Dusit University, Bangkok 10300, Thailand

²

Research Group for Fractional Calculus Theory and Applications, Science and Technology Research Institute, King Mongkut’s University of Technology North Bangkok, Bangkok 10800, Thailand

³

Jiangsu Key Laboratory for NSLSCS, School of Mathematical Sciences, Nanjing Normal University, Nanjing 210023, China

⁴

Department of Mathematics, Faculty of Science and Arts, Düzce University, Düzce 81620, Türkiye

^*

Author to whom correspondence should be addressed.

Fractal Fract. 2023, 7(8), 572; https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract7080572

Submission received: 16 June 2023 / Revised: 21 July 2023 / Accepted: 24 July 2023 / Published: 25 July 2023

(This article belongs to the Special Issue Fractional Integral Inequalities and Applications, 2nd Edition)

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Abstract

:

This work establishes some new inequalities to find error bounds for Maclaurin’s formulas in the framework of q-calculus. For this, we first prove an integral identity involving q-integral and q-derivative. Then, we use this new identity to prove some q-integral inequalities for q-differentiable convex functions. The inequalities proved here are very important in the literature because, with their help, we can find error bounds for Maclaurin’s formula in both q and classical calculus.

Keywords:

Maclaurin’s inequalities; Hermite–Hadamard inequalities; convex functions; q-calculus

1. Introduction

From the following Simpson’s rules, many inequalities of Simpson’s type were established:

(i.): Simpson’s $1 / 3$ rule:

$\int_{△_{1}}^{△_{2}} Υ (τ) d τ \approx \frac{△_{2} - △_{1}}{6} [Υ (△_{1}) + 4 Υ (\frac{△_{1} + △_{2}}{2}) + Υ (△_{2})] .$
(ii.): Simpson’s $3 / 8$ rule (cf. [1])):

$\int_{△_{1}}^{△_{2}} Υ (τ) d τ \approx \frac{△_{2} - △_{1}}{8} [Υ (△_{1}) + 3 Υ (\frac{2 △_{1} + △_{2}}{3}) + 3 Υ (\frac{△_{1} + 2 △_{2}}{3}) + Υ (△_{2})] .$
(iii.): Dual Simpson’s $3 / 8$ rule (cf. [1]):

$\int_{△_{1}}^{△_{2}} Υ (τ) d τ \approx \frac{△_{2} - △_{1}}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] .$

Now, we mention the inequalities linked to the above formulas to recall the literature. The Simpson’s inequality linked to the Simpson’s

1 / 3

formula is given as:

Theorem 1

([1]). For a four times differentiable and continuous function

Υ : [△_{1}, △_{2}] \to R .

The following inequality holds

\begin{matrix} |\frac{1}{6} [Υ (△_{1}) + 4 Υ (\frac{△_{1} + △_{2}}{2}) + Υ (△_{2})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ) d τ| \\ \leq \frac{1}{2880} sup_{τ \in (△_{1}, △_{2})} |Υ^{(4)} (τ)| {(△_{2} - △_{1})}^{4}, \end{matrix}

where

sup_{τ \in (△_{1}, △_{2})} |Υ^{(4)} (τ)| < \infty .

The Simpson’s inequality linked to the Simpson’s

3 / 8

formula is given as:

Theorem 2

([1]). For a four times differentiable and continuous function

Υ : [△_{1}, △_{2}] \to R .

The following inequality holds

\begin{matrix} |\frac{1}{8} [Υ (△_{1}) + 3 Υ (\frac{2 △_{1} + △_{2}}{3}) + 3 Υ (\frac{△_{1} + 2 △_{2}}{3}) + Υ (△_{2})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ) d τ| \\ \leq & \frac{1}{6480} {∥Υ^{(4)}∥}_{\infty} {(△_{2} - △_{1})}^{4}, \end{matrix}

where

sup_{τ \in (△_{1}, △_{2})} |Υ^{(4)} (τ)| < \infty .

The Simpson’s inequality linked to the dual Simpson’s

3 / 8

formula is given as:

Theorem 3

([1]). For a four times differentiable and continuous function

Υ : [△_{1}, △_{2}] \to R .

The following inequality holds

\begin{matrix} |\frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ) d τ| \\ \leq & \frac{7}{51840} {∥Υ^{(4)}∥}_{\infty} {(△_{2} - △_{1})}^{4}, \end{matrix}

where

sup_{τ \in (△_{1}, △_{2})} |Υ^{(4)} (τ)| < \infty .

Many authors have concentrated on obtaining new bounds for these quadrature formulas in recent years using a variety of justifications, including fractional integrals and convexities. For some of them, please refer to [2,3,4,5,6,7,8]. Several studies have been conducted on the subject of q-integral inequalities for various convexities. As an illustration, new inequalities of the Hermite–Hadamard, midpoint and trapezoidal type for q-integrals and q-differentiable convex functions were established in [9,10,11,12,13]. In order to prove Simpson’s type inequality for q-differentiable convex and generic convex functions, the authors of [14,15,16] used q-integral. One can refer to [17,18,19,20,21,22] for more recent q-calculus inequalities.

The aim of this paper is to establish new inequalities that can be utilized to determine error bounds for Maclaurin’s formulas within the framework of q-calculus. To achieve this objective, we begin by demonstrating an integral identity that incorporates both q-integral and q-derivative. Subsequently, we employ this novel identity to establish a series of q-integral inequalities specifically designed for q-differentiable convex functions. These inequalities hold significant importance in the existing literature since they enable us to determine error bounds for Maclaurin’s formula in both q-calculus and classical calculus. By developing these new inequalities, this work contributes to the advancement and understanding of error estimation techniques in mathematical analysis.

2. q-Calculus

To the better understanding about q-calculus, we gave some concepts of q-calculus here (see, [23]) and q is a real number in

(0, 1)

:

{[n]}_{q} = \frac{1 - q^{n}}{1 - q} = 1 + q + q^{2} + \dots + q^{n - 1} .

Definition 1

([22]). The left quantum or

q_{△_{1}}

-derivative of

Υ : [△_{1}, △_{2}] \to R

at

τ \in [△_{1}, △_{2}]

is expressed as:

\begin{matrix} _{△_{1}} D_{q} Υ (τ) \end{matrix} = \frac{Υ (τ) - Υ (q τ + (1 - q) △_{1})}{(1 - q) (τ - △_{1})}, τ \neq △_{1} .

(1)

Definition 2

([10]). The right quantum or

q^{△_{2}}

-derivative of

Υ : [△_{1}, △_{2}] \to R

at

τ \in [△_{1}, △_{2}]

is expressed as:

\begin{matrix} ^{△_{2}} D_{q} Υ (τ) \end{matrix} = \frac{Υ (q τ + (1 - q) △_{2}) - Υ (τ)}{(1 - q) (△_{2} - τ)}, τ \neq △_{2} .

Definition 3

([22]). The left quantum or

q_{△_{1}}

-integral of

Υ : [△_{1}, △_{2}] \to R

at

τ \in [△_{1}, △_{2}]

is defined as:

\int_{△_{1}}^{τ} Υ (ϰ) \begin{matrix} _{△_{1}} d_{q} ϰ \end{matrix} = (1 - q) (τ - △_{1}) \sum_{n = 0}^{\infty} q^{n} Υ (q^{n} τ + (1 - q^{n}) △_{1}) .

Definition 4

([10]). The right quantum or

q^{△_{2}}

-integral of

Υ : [△_{1}, △_{2}] \to R

at

τ \in [△_{1}, △_{2}]

is defined as:

\int_{τ}^{△_{2}} Υ (ϰ) \begin{matrix} ^{△_{2}} d_{q} ϰ \end{matrix} = (1 - q) (△_{2} - τ) \sum_{n = 0}^{\infty} q^{n} Υ (q^{n} τ + (1 - q^{n}) △_{2}) .

The following lemma will be used in our main results:

Lemma 1

([16]). For continuous functions

Υ, g : [△_{1}, △_{2}] \to R

, the following equality is true:

\begin{matrix} \int_{0}^{c} g (ϰ)_{△_{1}} D_{q} Υ (ϰ △_{2} + (1 - ϰ) △_{1}) d_{q} ϰ \\ = & {\frac{g (ϰ) Υ (ϰ △_{2} + (1 - ϰ) △_{1})}{△_{2} - △_{1}}|}_{0}^{c} - \frac{1}{△_{2} - △_{1}} \int_{0}^{c} D_{q} g (ϰ) Υ (q ϰ △_{2} + (1 - q ϰ) △_{1}) d_{q} ϰ . \end{matrix}

3. Main Results

In this section, we first obtain an identity for q-differentiable functions. Then, by using this equality, we establish some new Maclaurin’s type inequalities in q-calculus.

Lemma 2.

Let

Υ : [△_{1}, △_{2}] \to R

be a q-differentiable function. If

_{△_{1}} D_{q} Υ

is q-integrable function, then we have the following equality:

\begin{matrix} \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] \\ = & \frac{(△_{2} - △_{1})}{36} \sum_{j = 1}^{4} I_{j}, \end{matrix}

(2)

where

\begin{matrix} I_{1} & = & \int_{0}^{1} (1 - q ϰ)_{△_{1}} D_{q} Υ (\frac{1 - ϰ}{6} △_{1} + \frac{5 + ϰ}{6} △_{2}) d_{q} ϰ, \\ I_{2} & = & \int_{0}^{1} (\frac{3}{2} - 4 q ϰ)_{△_{1}} D_{q} Υ (\frac{3 - 2 ϰ}{6} △_{1} + \frac{3 + 2 ϰ}{6} △_{2}) d_{q} ϰ, \\ I_{3} & = & \int_{0}^{1} (\frac{5}{2} - 4 q ϰ)_{△_{1}} D_{q} Υ (\frac{5 - 2 ϰ}{6} △_{1} + \frac{1 + 2 ϰ}{6} △_{2}) d_{q} ϰ, \\ I_{4} & = & \int_{0}^{1} (- q ϰ)_{△_{1}} D_{q} Υ (\frac{6 - ϰ}{6} △_{1} + \frac{ϰ}{6} △_{2}) d_{q} ϰ . \end{matrix}

Proof.

By applying Lemma 1, we have:

\begin{matrix} I_{1} & = & \int_{0}^{1} (1 - q ϰ)_{△_{1}} D_{q} Υ (\frac{5 + ϰ}{6} △_{2} + \frac{1 - ϰ}{6} △_{1}) d_{q} ϰ \\ = & \int_{0}^{1} (1 - q ϰ)_{△_{1}} D_{q} Υ (ϰ △_{2} + (1 - ϰ) \frac{△_{1} + 5 △_{2}}{6}) d_{q} ϰ \\ = & \frac{6}{△_{2} - △_{1}} (1 - q) Υ (△_{2}) - \frac{6}{△_{2} - △_{1}} Υ (\frac{△_{1} + 5 △_{2}}{6}) \\ + \frac{6 q}{△_{2} - △_{1}} \int_{0}^{1} Υ (q ϰ △_{2} + (1 - q ϰ) \frac{△_{1} + 5 △_{2}}{6}) d_{q} ϰ \\ = & \frac{6}{△_{2} - △_{1}} (1 - q) Υ (△_{2}) - \frac{6}{△_{2} - △_{1}} Υ (\frac{△_{1} + 5 △_{2}}{6}) \\ + \frac{6 q}{△_{2} - △_{1}} [(1 - q) \sum_{n = 0}^{\infty} q^{n} Υ (q^{n + 1} △_{2} + (1 - q^{n + 1}) \frac{△_{1} + 5 △_{2}}{6})] \\ = & \frac{6}{△_{2} - △_{1}} (1 - q) Υ (△_{2}) - \frac{6}{△_{2} - △_{1}} Υ (\frac{△_{1} + 5 △_{2}}{6}) \\ + \frac{6}{△_{2} - △_{1}} [(1 - q) \sum_{n = 1}^{\infty} q^{n} Υ (q^{n} △_{2} + (1 - q^{n}) \frac{△_{1} + 5 △_{2}}{6})] \\ = & \frac{6}{△_{2} - △_{1}} (1 - q) Υ (△_{1}) - \frac{6}{△_{2} - △_{1}} Υ (\frac{△_{1} + 5 △_{2}}{6}) \\ + \frac{6}{△_{2} - △_{1}} [(1 - q) \sum_{n = 0}^{\infty} q^{n} Υ (q^{n} △_{2} + (1 - q^{n}) \frac{△_{1} + 5 △_{2}}{6}) - (1 - q) Υ (△_{2})] \\ = & \frac{6 (1 - q)}{△_{2} - △_{1}} \sum_{n = 0}^{\infty} q^{n} Υ (q^{n} △_{2} + (1 - q^{n}) \frac{△_{1} + 5 △_{2}}{6}) - \frac{6}{△_{2} - △_{1}} Υ (\frac{△_{1} + 5 △_{2}}{6}) . \end{matrix}

By Definition 3, we can write:

I_{1} = \frac{36}{{(△_{2} - △_{1})}^{2}} \int_{\frac{△_{1} + 5 △_{2}}{6}}^{△_{2}} Υ (τ)_{\frac{△_{1} + 5 △_{2}}{6}} d_{q} τ - \frac{6}{△_{2} - △_{1}} Υ (\frac{△_{1} + 5 △_{2}}{6}) .

(3)

Similarly, by Lemma 1 and Definition 3, one can obtain

\begin{matrix} I_{2} & = & \int_{0}^{1} (\frac{3}{2} - 4 q ϰ)_{△_{1}} D_{q} Υ (\frac{3 - 2 ϰ}{6} △_{1} + \frac{3 + 2 ϰ}{6} △_{2}) d_{q} ϰ \\ = & \frac{36}{{(△_{2} - △_{1})}^{2}} \int_{\frac{△_{1} + △_{2}}{2}}^{\frac{△_{1} + 5 △_{2}}{6}} Υ (τ)_{\frac{△_{1} + △_{2}}{2}} d_{q} τ - \frac{15}{2} Υ (\frac{△_{1} + 5 △_{2}}{6}) \\ - \frac{9}{2 (△_{2} - △_{1})} Υ (\frac{△_{1} + △_{2}}{2}), \end{matrix}

(4)

\begin{matrix} I_{3} & = & \int_{0}^{1} (\frac{5}{2} - 4 q ϰ)_{△_{1}} D_{q} Υ (\frac{5 - 2 ϰ}{6} △_{1} + \frac{1 + 2 ϰ}{6} △_{2}) d_{q} ϰ \\ = & \frac{36}{{(△_{2} - △_{1})}^{2}} \int_{\frac{5 △_{1} + △_{2}}{6}}^{\frac{△_{1} + △_{2}}{2}} Υ (τ)_{\frac{5 △_{1} + △_{2}}{6}} d_{q} τ - \frac{9}{2 (△_{2} - △_{1})} Υ (\frac{△_{1} + △_{2}}{2}) \\ - \frac{15}{2 (△_{2} - △_{1})} Υ (\frac{5 △_{1} + △_{2}}{6}) \end{matrix}

(5)

and

\begin{matrix} I_{4} & = & \int_{0}^{1} (- q ϰ)_{△_{1}} D_{q} Υ (\frac{6 - ϰ}{6} △_{1} + \frac{ϰ}{6} △_{2}) d_{q} ϰ \\ = & \frac{36}{{(△_{2} - △_{1})}^{2}} \int_{△_{1}}^{\frac{5 △_{1} + △_{2}}{6}} Υ (τ)_{△_{1}} d_{q} τ - \frac{6}{△_{2} - △_{1}} Υ (\frac{5 △_{1} + △_{2}}{6}) . \end{matrix}

(6)

Thus, we achieve the required equality by the adding equalities (3)–(6). □

Theorem 4.

Let all the conditions of Lemma 2 be hold. If

|_{△_{1}} D_{q} Υ|

is a convex functions, then the following inequality holds

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [(\frac{1}{{[2]}_{q}} + \frac{1}{6} (5 A_{1} (q) + 3 A_{2} (q) + 3 A_{3} (q) + A_{4} (q))) |_{△_{1}} D_{q} Υ (△_{2})| \\ + (\frac{q}{{[2]}_{q}} + \frac{1}{6} (A_{1} (q) + 3 A_{2} (q) + 3 A_{3} (q) + 5 A_{4} (q))) |_{△_{1}} D_{q} Υ (△_{1})|, \end{matrix}

where

\begin{matrix} A_{1} (q) & = & \int_{0}^{1} |\frac{3}{2} - 4 q ϰ| ϰ d_{q} ϰ = \{\begin{matrix} \frac{3 - 5 q - 5 q^{2}}{2 {[2]}_{q} {[3]}_{q}}, 0 < q < \frac{3}{8} \\ \frac{160 q^{2} + 160 q - 69}{64 {[2]}_{q} {[3]}_{q}}, \frac{3}{8} < q < 1, \end{matrix} \\ A_{2} (q) & = & \int_{0}^{1} |\frac{3}{2} - 4 q ϰ| (1 - ϰ) d_{q} ϰ = \{\begin{matrix} \frac{3 q + 3 q^{2} - 5 q^{3}}{2 {[2]}_{q} {[3]}_{q}}, 0 < q < \frac{3}{8} \\ \frac{160 q^{3} - 24 q^{2} - 24 q + 45}{64 {[2]}_{q} {[3]}_{q}}, \frac{3}{8} < q < 1 \end{matrix} \\ A_{3} (q) & = & \int_{0}^{1} |\frac{5}{2} - 4 q ϰ| ϰ d_{q} ϰ = \{\begin{matrix} \frac{5 - 3 q^{2} - 3 q}{2 {[2]}_{q} {[3]}_{q}}, 0 < q < \frac{5}{8} \\ \frac{96 q^{2} + 96 q - 35}{64 {[2]}_{q} {[3]}_{q}}, \frac{5}{8} < q < 1 \end{matrix} \\ A_{4} (q) & = & \int_{0}^{1} |\frac{5}{2} - 4 q ϰ| (1 - ϰ) d_{q} ϰ = \{\begin{matrix} \frac{5 q + 5 q^{2} - 3 q^{2}}{2 {[2]}_{q} {[3]}_{q}}, 0 < q < \frac{5}{8} \\ \frac{96 q^{3} + 40 q^{2} + 40 q + 75}{64 {[2]}_{q} {[3]}_{q}}, \frac{5}{8} < q < 1 . \end{matrix} \end{matrix}

Proof.

By taking modulus in Lemma 2, we have:

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ \\ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [|I_{1}| + |I_{2}| + |I_{3}| + |I_{4}|] . \end{matrix}

(7)

Since

|_{△_{1}} D_{q} Υ|

is convex, we obtain:

\begin{matrix} |I_{1}| & \leq & \int_{0}^{1} (1 - q ϰ) |_{△_{1}} D_{q} Υ (\frac{5 + ϰ}{6} △_{2} + \frac{1 - ϰ}{6} △_{1})| d_{q} ϰ \\ = & \int_{0}^{1} (1 - q ϰ) [|_{△_{1}} D_{q} Υ (ϰ △_{2} + (1 - ϰ) \frac{△_{1} + 5 △_{2}}{6})|] d_{q} ϰ \\ \leq & \int_{0}^{1} (1 - q ϰ) [ϰ |_{△_{1}} D_{q} Υ (△_{2})| + (1 - ϰ) |_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})|] d_{q} ϰ \\ = & |_{△_{1}} D_{q} Υ (△_{2})| (\int_{0}^{1} ϰ (1 - q ϰ) d_{q} ϰ) \\ + |_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})| (\int_{0}^{1} (1 - ϰ) (1 - q ϰ) d_{q} ϰ) \\ = & \frac{|_{△_{1}} D_{q} Υ (△_{2})|}{{[2]}_{q} {[3]}_{q}} + \frac{q |_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})|}{{[3]}_{q}} \\ \leq & \frac{|_{△_{1}} D_{q} Υ (△_{2})|}{{[2]}_{q} {[3]}_{q}} + \frac{q (\frac{|_{△_{1}} D_{q} Υ (△_{1})| + 5 |_{△_{1}} D_{q} Υ (△_{2})|}{6})}{{[3]}_{q}} \\ = & \frac{|_{△_{1}} D_{q} Υ (△_{1})|}{{[2]}_{q} {[3]}_{q}} + \frac{q (|_{△_{1}} D_{q} Υ (△_{1})| + 5 |_{△_{1}} D_{q} Υ (△_{2})|)}{6 {[3]}_{q}} \\ = & (\frac{5 q^{2} + 5 q + 6}{6 {[2]}_{q} {[3]}_{q}}) |_{△_{1}} D_{q} Υ (△_{2})| + \frac{q}{6 {[3]}_{q}} |_{△_{1}} D_{q} Υ (△_{1})| . \end{matrix}

(8)

Similarly, one can establish

\begin{matrix} |I_{2}| & \leq & \int_{0}^{1} |\frac{3}{2} - 4 q ϰ| |^{△_{2}} D_{q} Υ (\frac{3 + 2 ϰ}{6} △_{2} + \frac{3 - 2 ϰ}{6} △_{1})| d_{q} ϰ \\ \leq & \int_{0}^{1} |\frac{3}{2} - 4 q ϰ| [ϰ |_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})| + (1 - ϰ) |_{△_{1}} D_{q} Υ (\frac{△_{1} + △_{2}}{2})|] d_{q} ϰ \\ = & A_{1} (q) |_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})| + A_{2} (q) |_{△_{1}} D_{q} Υ (\frac{△_{1} + △_{2}}{2})| \\ \leq & A_{1} (q) [\frac{|_{△_{1}} D_{q} Υ (△_{1})| + 5 |_{△_{1}} D_{q} Υ (△_{2})|}{6}] + A_{2} (q) [\frac{|_{△_{1}} D_{q} Υ (△_{1})| + |_{△_{1}} D_{q} Υ (△_{2})|}{2}] \\ = & [\frac{5 A_{1} (q) + 3 A_{2} (q)}{6}] |_{△_{1}} D_{q} Υ (△_{2})| + [\frac{A_{1} (q) + 3 A_{2} (q)}{6}] |_{△_{1}} D_{q} Υ (△_{1})|, \end{matrix}

(9)

\begin{matrix} |I_{3}| & \leq & \int_{0}^{1} |\frac{5}{2} - 4 q ϰ| |^{△_{2}} D_{q} Υ (\frac{1 + 2 ϰ}{6} △_{2} + \frac{5 - 2 ϰ}{6} △_{1})| d_{q} ϰ \\ \leq & \int_{0}^{1} |\frac{5}{2} - 4 q ϰ| [ϰ |_{△_{1}} D_{q} Υ (\frac{△_{1} + △_{2}}{2})| + (1 - ϰ) |_{△_{1}} D_{q} Υ (\frac{5 △_{1} + △_{2}}{6})|] d ϰ \\ = & A_{3} (q) |_{△_{1}} D_{q} Υ (\frac{△_{1} + △_{2}}{2})| + A_{4} (q) |_{△_{1}} D_{q} Υ (\frac{5 △_{1} + △_{2}}{6})| \\ \leq & A_{3} (q) [\frac{|_{△_{1}} D_{q} Υ (△_{1})| + |_{△_{1}} D_{q} Υ (△_{2})|}{2}] + A_{4} (q) [\frac{5 |_{△_{1}} D_{q} Υ (△_{1})| + |_{△_{1}} D_{q} Υ (△_{2})|}{6}] \\ = & [\frac{3 A_{3} (q) + A_{4} (q)}{6}] |_{△_{1}} D_{q} Υ (△_{2})| + [\frac{3 A_{3} (q) + 5 A_{4} (q)}{6}] |_{△_{1}} D_{q} Υ (△_{1})| \end{matrix}

(10)

and

\begin{matrix} |I_{4}| & \leq & \int_{0}^{1} q ϰ |^{△_{2}} D_{q} Υ (\frac{ϰ}{6} △_{2} + \frac{6 - ϰ}{6} △_{1})| d_{q} ϰ \\ \leq & \int_{0}^{1} q ϰ [(1 - ϰ) |_{△_{1}} D_{q} Υ (△_{1})| + ϰ |_{△_{1}} D_{q} Υ (\frac{5 △_{1} + △_{2}}{6})|] \\ = & \frac{q^{3} |_{△_{1}} D_{q} Υ (△_{1})|}{{[2]}_{q} {[3]}_{q}} + \frac{q |_{△_{1}} D_{q} Υ (\frac{5 △_{1} + △_{2}}{6})|}{{[3]}_{q}} \\ \leq & \frac{q^{3} |_{△_{1}} D_{q} Υ (△_{1})|}{{[2]}_{q} {[3]}_{q}} + [\frac{q (5 |_{△_{1}} D_{q} Υ (△_{1})| + |_{△_{1}} D_{q} Υ (△_{2})|)}{6 {[3]}_{q}}] \\ = & [\frac{6 q^{3} + 5 q^{2} + 5 q}{6 {[2]}_{q} {[3]}_{q}}] |_{△_{1}} D_{q} Υ (△_{1})| + \frac{q}{6 {[3]}_{q}} |_{△_{1}} D_{q} Υ (△_{2})| . \end{matrix}

(11)

Thus, by using (8)–(11) in (7), we obtain the resultant inequality. □

Example 1.

Let consider the function

Υ : [1, 2] \to R,

Υ (ϰ) = ϰ^{3}

with

q = \frac{3}{4}

. Since

_{△_{1}} D_{q} Υ (τ) =_{1} D_{\frac{3}{4}} τ^{3} = \frac{τ^{3} - (\frac{4}{3} τ + \frac{1}{4})}{\frac{1}{4} (τ - 1)} = \frac{37}{16} τ^{2} + \frac{5}{8} τ + \frac{1}{16},

then

|_{△_{1}} D_{q} Υ|

is convex on

[1, 2] .

Therefore, Theorem 4 can be applied for the function

Υ (ϰ) = ϰ^{3}

. By Definition 3,

\begin{matrix} \int_{△_{1}}^{△_{2}} Υ (ϰ)_{△_{1}} d_{q} ϰ & = & \int_{1}^{2} ϰ^{3}_{1} d_{\frac{3}{4}} ϰ = \frac{1}{4} \sum_{n = 0}^{\infty} {(\frac{3}{4})}^{n} {({(\frac{3}{4})}^{n} + 1)}^{3} \\ = & \frac{1}{4} \sum_{n = 0}^{\infty} {(\frac{3}{4})}^{n} ({(\frac{3}{4})}^{3 n} + 3 {(\frac{3}{4})}^{2 n} + 3 {(\frac{3}{4})}^{n} + 1) \\ = & \frac{1}{4} [\frac{1}{1 - \frac{81}{256}} + \frac{3}{1 - \frac{27}{64}} + \frac{1}{1 - \frac{9}{16}} + \frac{1}{1 - \frac{3}{4}}] \\ = & \frac{20943}{6475} . \end{matrix}

On the other hand,

\begin{matrix} \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] \\ = & \frac{1}{8} [3 {(\frac{7}{6})}^{3} + 2 {(\frac{1}{2})}^{3} + {(\frac{11}{6})}^{3}] \\ = & \frac{1207}{864} . \end{matrix}

Thus, the left hand side of Theorem 4 reduces

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ = & |\frac{20943}{6475} - \frac{1207}{864}| \\ ≅ & 1.8375 . \end{matrix}

On the other hand, for

q = \frac{3}{4}

, we have

\begin{matrix} A_{1} (\frac{3}{4}) & = & \frac{160 {(\frac{3}{4})}^{2} + 160 \frac{3}{4} - 69}{64 (1 + \frac{3}{4}) (1 + \frac{3}{4} + {(\frac{3}{4})}^{2})} = \frac{141}{259} \\ A_{2} (\frac{3}{4}) & = & \frac{160 {(\frac{3}{4})}^{3} - 24 {(\frac{3}{4})}^{2} - 24 \frac{3}{4} + 45}{64 (1 + \frac{3}{4}) (1 + \frac{3}{4} + {(\frac{3}{4})}^{2})} = \frac{81}{259} \\ A_{3} (\frac{3}{4}) & = & \frac{96 {(\frac{3}{4})}^{2} + 96 \frac{3}{4} - 35}{64 (1 + \frac{3}{4}) (1 + \frac{3}{4} + {(\frac{3}{4})}^{2})} = \frac{13}{37} \\ A_{4} (\frac{3}{4}) & = & \frac{96 {(\frac{3}{4})}^{3} + 40 {(\frac{3}{4})}^{2} + 40 \frac{3}{4} + 75}{64 (1 + \frac{3}{4}) (1 + \frac{3}{4} + {(\frac{3}{4})}^{2})} = \frac{24}{37} . \end{matrix}

Moreover, since

_{△_{1}} D_{q} Υ (τ) = \frac{37}{16} τ^{2} + \frac{5}{8} τ + \frac{1}{16},

we obtain

\begin{matrix} |_{△_{1}} D_{q} Υ (△_{2})| & = & |_{1} D_{\frac{3}{4}} Υ (2)| = \frac{633}{16} \\ |_{△_{1}} D_{q} Υ (△_{1})| & = & |_{1} D_{\frac{3}{4}} Υ (1)| = 3 . \end{matrix}

Consequently, we can calculate the right hand side of Theorem 4 as

\begin{matrix} \frac{△_{2} - △_{1}}{36} [(\frac{1}{{[2]}_{q}} + \frac{1}{6} (5 A_{1} (q) + 3 A_{2} (q) + 3 A_{3} (q) + A_{4} (q))) |_{△_{1}} D_{q} Υ (△_{2})| \\ + (\frac{q}{{[2]}_{q}} + \frac{1}{6} (A_{1} (q) + 3 A_{2} (q) + 3 A_{3} (q) + 5 A_{4} (q))) |_{△_{1}} D_{q} Υ (△_{1})|] \\ = & \frac{1}{36} [3 (\frac{4}{7} + \frac{1}{6} (5 \frac{141}{259} + 3 \frac{81}{259} + 3 \frac{13}{37} + \frac{24}{37})) \\ + \frac{633}{16} (\frac{3}{7} + \frac{1}{6} (\frac{141}{259} + 3 \frac{81}{259} + 3 \frac{13}{37} + 5 \frac{24}{37}))] \\ = & \frac{1}{36} (\frac{57}{7} + \frac{5697}{56}) \\ = & \frac{293}{96} \\ ≅ & 3.052 . \end{matrix}

Since

1.8375 \leq 3.052,

it is clear that Theorem 4 is valid for the function

Υ (ϰ) = ϰ^{3}

.

Remark 1.

If we set limit as

q \to 1^{-}

in Theorem 4, then we obtain the following inequality:

\begin{matrix} |\frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ) d τ| \\ \leq & \frac{25 (△_{2} - △_{1})}{576} [|Υ^{'} (△_{1})| + |Υ^{'} (△_{2})|] . \end{matrix}

This inequality can be found as a special case of [7].

Theorem 5.

Let all the conditions of Lemma 2 be hold. If

{|_{△_{1}} D_{q} Υ|}^{r}

,

r \geq 1

is a convex function, then the following inequality holds

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\frac{1}{{[2]}_{q}})}^{1 - \frac{1}{r}} {((\frac{5 q^{2} + 5 q + 6}{6 {[2]}_{q} {[3]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{q}{6 {[3]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{5} (q))}^{1 - \frac{1}{r}} {([\frac{5 A_{1} (q) + 3 A_{2} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + [\frac{A_{1} (q) + 3 A_{2} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{6} (q))}^{1 - \frac{1}{r}} {([\frac{3 A_{3} (q) + A_{4} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + [\frac{3 A_{3} (q) + 5 A_{4} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(\frac{q}{{[2]}_{q}})}^{1 - \frac{1}{r}} {([\frac{6 q^{3} + 5 q^{2} + 5 q}{6 {[2]}_{q} {[3]}_{q}}] {|_{△_{1}} D_{q} Υ (△_{1})|}^{r} + \frac{q}{6 {[3]}_{q}} {|_{△_{1}} D_{q} Υ (△_{2})|}^{r})}^{\frac{1}{r}}], \end{matrix}

where

A_{1} (q) - A_{4} (q)

are same as defined in the Theorem 4 and

A_{5} (q) = \{\begin{matrix} \frac{3 - 5 q}{2 {[2]}_{q}}, 0 < q < \frac{3}{8} \\ \frac{20 q - 3}{8 {[2]}_{q}}, \frac{3}{8} < q < 1, \end{matrix}

A_{6} (q) = \{\begin{matrix} \frac{5 - 3 q}{2 {[2]}_{q}}, 0 < q < \frac{5}{8} \\ \frac{37 - 20 q}{8 {[2]}_{q}}, \frac{5}{8} < q < 1 . \end{matrix}

Proof.

By using power mean inequality in (7), we obtain:

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [|I_{1}| + |I_{2}| + |I_{3}| + |I_{4}|] \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\int_{0}^{1} (1 - q ϰ) d_{q} ϰ)}^{1 - \frac{1}{r}} {(\int_{0}^{1} (1 - q ϰ) {|_{△_{1}} D_{q} Υ (\frac{5 + ϰ}{6} △_{2} + \frac{1 - ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}} \\ + {(\int_{0}^{1} |\frac{3}{2} - 4 q ϰ| d_{q} ϰ)}^{1 - \frac{1}{r}} {(\int_{0}^{1} |\frac{3}{2} - 4 q ϰ| {|_{△_{1}} D_{q} Υ (\frac{3 + 2 ϰ}{6} △_{2} + \frac{3 - 2 ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}} \\ + {(\int_{0}^{1} |\frac{5}{2} - 4 q ϰ| d_{q} ϰ)}^{1 - \frac{1}{r}} {(\int_{0}^{1} |\frac{5}{2} - 4 q ϰ| {|_{△_{1}} D_{q} Υ (\frac{1 + 2 ϰ}{6} △_{2} + \frac{5 - 2 ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}} \\ + {(\int_{0}^{1} q ϰ d_{q} ϰ)}^{1 - \frac{1}{r}} {(\int_{0}^{1} q ϰ {|_{△_{1}} D_{q} Υ (\frac{ϰ}{6} △_{2} + \frac{6 - ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}}] . \end{matrix}

By using the convexity of

{|_{△_{1}} D_{q} Υ|}^{r}

, we have:

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\frac{1}{{[2]}_{q}})}^{1 - \frac{1}{r}} {((\frac{5 q^{2} + 5 q + 6}{6 {[2]}_{q} {[3]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{q}{6 {[3]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{5} (q))}^{1 - \frac{1}{r}} {([\frac{5 A_{1} (q) + 3 A_{2} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + [\frac{A_{1} (q) + 3 A_{2} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{6} (q))}^{1 - \frac{1}{r}} {([\frac{3 A_{3} (q) + A_{4} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + [\frac{3 A_{3} (q) + 5 A_{4} (q)}{6}] {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(\frac{q}{{[2]}_{q}})}^{1 - \frac{1}{r}} {([\frac{6 q^{3} + 5 q^{2} + 5 q}{6 {[2]}_{q} {[3]}_{q}}] {|_{△_{1}} D_{q} Υ (△_{1})|}^{r} + \frac{q}{6 {[3]}_{q}} {|_{△_{1}} D_{q} Υ (△_{2})|}^{r})}^{\frac{1}{r}}] . \end{matrix}

Thus, the proof is completed. □

Remark 2.

If we set the limit as

q \to 1^{-}

in Theorem 5, then we have the following inequality:

\begin{matrix} |\frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ) d τ| \\ \leq & \frac{△_{2} - △_{1}}{36} [\frac{1}{2} \{{(\frac{8 {|Υ^{'} (△_{1})|}^{r} + {|Υ^{'} (△_{2})|}^{r}}{9})}^{\frac{1}{r}} + {(\frac{{|Υ^{'} (△_{1})|}^{r} + 8 {|Υ^{'} (△_{2})|}^{r}}{9})}^{\frac{1}{r}}\} \\ + \frac{17}{16} \{{(\frac{1726 {|Υ^{'} (△_{1})|}^{r} + 722 {|Υ^{'} (△_{2})|}^{r}}{9})}^{\frac{1}{r}} + {(\frac{722 {|Υ^{'} (△_{1})|}^{r} + 1726 {|Υ^{'} (△_{2})|}^{r}}{9})}^{\frac{1}{r}}\} . \end{matrix}

This inequality can be found as a special case of [7].

Theorem 6.

Let all the conditions of Lemma 2 be hold. If

{|_{△_{1}} D_{q} Υ|}^{r}

,

r > 1

is a convex function, then the following inequality holds

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\frac{1 - {(1 - q)}^{s + 1}}{q (s + 1)})}^{\frac{1}{s}} {((\frac{6 + 5 q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{7} (q, s))}^{\frac{1}{s}} {((\frac{5 + 3 q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{1 + 3 q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{8} (q, s))}^{\frac{1}{s}} {((\frac{3 + q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{3 + 5 q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(\frac{q^{s}}{(s + 1)})}^{\frac{1}{s}} {((\frac{6 + 5 q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{1})|}^{r} + \frac{q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{2})|}^{r})}^{\frac{1}{r}}], \end{matrix}

where

r^{- 1} + s^{- 1} = r s

and

A_{7} (q, s) = \{\begin{matrix} \frac{3^{s + 1} - {(3 - 8 q)}^{s + 1}}{2^{s + 3} q (s + 1)}, 0 < q < \frac{3}{8} \\ \frac{3^{s + 1} - {(8 q - 3)}^{s + 1}}{2^{s + 3} q (s + 1)}, \frac{3}{8} < q < 1, \end{matrix}

A_{8} (q, s) = \{\begin{matrix} \frac{5^{s + 1} - {(5 - 8 q)}^{s + 1}}{2^{s + 3} q (s + 1)}, 0 < q < \frac{5}{8} \\ \frac{5^{s + 1} - {(8 q - 5)}^{s + 1}}{2^{s + 3} q (s + 1)}, \frac{5}{8} < q < 1 . \end{matrix}

Proof.

Taking modulus in (2) and using Hölder’s inequality, we have:

\begin{matrix} |\frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)_{△_{1}} d_{q} τ - \frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})]| \\ \leq & \frac{△_{2} - △_{1}}{36} [|I_{1}| + |I_{2}| + |I_{3}| + |I_{4}|] \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\int_{0}^{1} {(1 - q ϰ)}^{s} d_{q} ϰ)}^{\frac{1}{s}} {(\int_{0}^{1} {|_{△_{1}} D_{q} Υ (\frac{5 + ϰ}{6} △_{2} + \frac{1 - ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}} \\ + {(\int_{0}^{1} {|\frac{3}{2} - 4 q ϰ|}^{s} d_{q} ϰ)}^{\frac{1}{s}} {(\int_{0}^{1} {|_{△_{1}} D_{q} Υ (\frac{3 + 2 ϰ}{6} △_{2} + \frac{3 - 2 ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}} \\ + {(\int_{0}^{1} {|\frac{5}{2} - 4 q ϰ|}^{s} d_{q} ϰ)}^{\frac{1}{s}} {(\int_{0}^{1} {|_{△_{1}} D_{q} Υ (\frac{1 + 2 ϰ}{6} △_{2} + \frac{5 - 2 ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}} \\ + {(\int_{0}^{1} {(q ϰ)}^{s} d_{q} ϰ)}^{\frac{1}{s}} {(\int_{0}^{1} {|_{△_{1}} D_{q} Υ (\frac{ϰ}{6} △_{2} + \frac{6 - ϰ}{6} △_{1})|}^{r} d_{q} ϰ)}^{\frac{1}{r}}] . \end{matrix}

Now from convexity, we have

\begin{matrix} |\frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ)^{△_{2}} d_{q} τ| \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\frac{1 - {(1 - q)}^{s + 1}}{q (s + 1)})}^{\frac{1}{s}} {(\frac{1}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{q}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})|}^{r})}^{\frac{1}{r}} \\ + {(A_{7} (q, s))}^{\frac{1}{s}} {(\frac{1}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (\frac{△_{1} + 5 △_{2}}{6})|}^{r} + \frac{q}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (\frac{△_{1} + △_{2}}{2})|}^{r})}^{\frac{1}{r}} \\ + {(A_{8} (q, s))}^{\frac{1}{s}} {(\frac{1}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (\frac{△_{1} + △_{2}}{2})|}^{r} + \frac{q}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (\frac{5 △_{1} + △_{2}}{6})|}^{r})}^{\frac{1}{r}} \\ + {(\frac{q^{s}}{s + 1})}^{\frac{1}{s}} {(\frac{q}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r} + \frac{1}{{[2]}_{q}} {|_{△_{1}} D_{q} Υ (\frac{5 △_{1} + △_{2}}{6})|}^{r})}^{\frac{1}{r}}] \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\frac{1 - {(1 - q)}^{s + 1}}{q (s + 1)})}^{\frac{1}{s}} {((\frac{6 + 5 q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{7} (q, s))}^{\frac{1}{s}} {((\frac{5 + 3 q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{1 + 3 q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(A_{8} (q, s))}^{\frac{1}{s}} {((\frac{3 + q}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{2})|}^{r} + \frac{3 + 5 q}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{1})|}^{r})}^{\frac{1}{r}} \\ + {(\frac{q^{s}}{s + 1})}^{\frac{1}{s}} {((\frac{6 q + 5}{6 {[2]}_{q}}) {|_{△_{1}} D_{q} Υ (△_{1})|}^{r} + \frac{1}{6 {[2]}_{q}} {|_{△_{1}} D_{q} Υ (△_{2})|}^{r})}^{\frac{1}{r}}] . \end{matrix}

Thus, the proof is completed. □

Remark 3.

If we set the limit as

q \to 1^{-}

in Theorem 6, then we have the following inequality:

\begin{matrix} |\frac{1}{8} [3 Υ (\frac{5 △_{1} + △_{2}}{6}) + 2 Υ (\frac{△_{1} + △_{2}}{2}) + 3 Υ (\frac{△_{1} + 5 △_{2}}{6})] - \frac{1}{△_{2} - △_{1}} \int_{△_{1}}^{△_{2}} Υ (τ) d τ| \\ \leq & \frac{△_{2} - △_{1}}{36} [{(\frac{1}{s + 1})}^{\frac{1}{s}} \{{(\frac{11 {|Υ^{'} (△_{1})|}^{r} + {|Υ^{'} (△_{2})|}^{r}}{12})}^{\frac{1}{r}} + {(\frac{{|Υ^{'} (△_{1})|}^{r} + 11 {|Υ^{'} (△_{2})|}^{r}}{12})}^{\frac{1}{r}}\} \\ + \frac{1}{2} {(\frac{3^{s + 1} + 5^{s + 1}}{8})}^{\frac{1}{s}} \{{(\frac{2 {|Υ^{'} (△_{1})|}^{r} + {|Υ^{'} (△_{2})|}^{r}}{3})}^{\frac{1}{r}} + {(\frac{{|Υ^{'} (△_{1})|}^{r} + 2 {|Υ^{'} (△_{2})|}^{r}}{3})}^{\frac{1}{r}}\} . \end{matrix}

This inequality can be found as a special case of [7].

4. Conclusions

In this paper, we used the left q-derivative and integral to prove some new Maclaurin’s formula type inequalities for q-differentiable convex functions. It is also shown that the newly established inequalities are extensions of some existing inequalities in the literature. The inequalities presented in this work are very important because, with the help of these inequalities, we can find error bounds for Maclaurin’s formula in classical and q-calculus. It is a very interesting and novel problem, and it is hoped that future researchers will be able to establish similar inequalities for co-ordinated convex functions.

Author Contributions

Conceptualization, T.S. and M.A.A.; funding acquisition, T.S.; investigation, M.A.A. and H.B.; methodology, T.S. and M.A.A.; validation, H.B.; visualization, T.S. and H.B.; writing—original draft, M.A.A.; writing—review and editing, T.S. and H.B. All authors have read and agreed to the published version of the manuscript.

Funding

This research has received funding support from the NSRF via the Program Management Unit for Human Resources and Institutional Development, Research and Innovation [grant number B05F640163]. This work was also partially supported by National Natural Science Foundation of China (No. 11971241).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Sitthiwirattham, T.; Ali, M.A.; Budak, H. On Some New Maclaurin’s Type Inequalities for Convex Functions in q-Calculus. Fractal Fract. 2023, 7, 572. https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract7080572

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Sitthiwirattham T, Ali MA, Budak H. On Some New Maclaurin’s Type Inequalities for Convex Functions in q-Calculus. Fractal and Fractional. 2023; 7(8):572. https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract7080572

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Sitthiwirattham, Thanin, Muhammad Aamir Ali, and Hüseyin Budak. 2023. "On Some New Maclaurin’s Type Inequalities for Convex Functions in q-Calculus" Fractal and Fractional 7, no. 8: 572. https://0-doi-org.brum.beds.ac.uk/10.3390/fractalfract7080572

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On Some New Maclaurin’s Type Inequalities for Convex Functions in q-Calculus

Abstract

1. Introduction

2. q-Calculus

3. Main Results

4. Conclusions

Author Contributions

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