New general integral inequalities for quasi-geometrically convex functions via fractional integrals

İşcan, İmdat

doi:10.1186/1029-242X-2013-491

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Published: 07 November 2013

New general integral inequalities for quasi-geometrically convex functions via fractional integrals

İmdat İşcan¹

Journal of Inequalities and Applications volume 2013, Article number: 491 (2013) Cite this article

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Abstract

In this paper, the author introduces the concept of the quasi-geometrically convex functions, gives Hermite-Hadamard’s inequalities for GA-convex functions in fractional integral forms and defines a new identity for fractional integrals. By using this identity, the author obtains new estimates on generalization of Hadamard et al. type inequalities for quasi-geometrically convex functions via Hadamard fractional integrals.

MSC:26A33, 26A51, 26D15.

1 Introduction

Let a real function f be defined on some nonempty interval I of a real line ℝ. The function f is said to be convex on I if inequality

f (t x + (1 - t) y) \leq t f (x) + (1 - t) f (y)

(1)

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

We recall that the notion of quasi-convex function generalizes the notion of convex function. More exactly, a function $f : [a, b] \subset R \to R$ is said to be quasi-convex on $[a, b]$ if

f (t x + (1 - t) y) \leq max {f (x), f (y)}

for all $x, y \in [a, b]$ and $t \in [0, 1]$ . Clearly, any convex function is a quasi-convex function. Furthermore, there exist quasi-convex functions which are not convex (see [1]).

The following inequalities are well known in the literature as the Hermite-Hadamard inequality, the Ostrowski inequality and the Simpson inequality, respectively.

Theorem 1.1 Let $f : I \subseteq R \to R$ be a convex function defined on the interval I of real numbers, and let $a, b \in I$ with $a < b$ . The following double inequality holds:

f (\frac{a + b}{2}) \leq \frac{1}{b - a} \int_{a}^{b} f (x) d x \leq \frac{f (a) + f (b)}{2} .

(2)

Theorem 1.2 Let $f : I \subseteq R \to R$ be a mapping differentiable in $I^{\circ}$ , the interior of I, and let $a, b \in I^{\circ}$ with $a < b$ . If $| f^{'} (x) | \leq M$ , $x \in [a, b]$ , then the following inequality holds:

| f (x) - \frac{1}{b - a} \int_{a}^{b} f (t) d t | \leq \frac{M}{b - a} [\frac{{(x - a)}^{2} + {(b - x)}^{2}}{2}]

for all $x \in [a, b]$ .

Theorem 1.3 Let $f : [a, b] \to R$ be a four times continuously differentiable mapping on $(a, b)$ and ${∥ f^{(4)} ∥}_{\infty} = {sup}_{x \in (a, b)} | f^{(4)} (x) | < \infty$ . Then the following inequality holds:

| \frac{1}{3} [\frac{f (a) + f (b)}{2} + 2 f (\frac{a + b}{2})] - \frac{1}{b - a} \int_{a}^{b} f (x) d x | \leq \frac{1}{2, 880} {∥ f^{(4)} ∥}_{\infty} {(b - a)}^{4} .

The following definitions are well known in the literature.

Definition 1.1 ([2, 3])

A function $f : I \subseteq (0, \infty) \to R$ is said to be GA-convex (geometric-arithmetically convex) if

f (x^{t} y^{1 - t}) \leq t f (x) + (1 - t) f (y)

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

Definition 1.2 ([2, 3])

A function $f : I \subseteq (0, \infty) \to (0, \infty)$ is said to be GG-convex (called in [4] a geometrically convex function) if

f (x^{t} y^{1 - t}) \leq f {(x)}^{t} f {(y)}^{(1 - t)}

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

We will now give definitions of the right-hand side and left-hand side Hadamard fractional integrals which are used throughout this paper.

Definition 1.3 Let $f \in L [a, b]$ . The right-hand side and left-hand side Hadamard fractional integrals $J_{a^{+}}^{α} f$ and $J_{b^{-}}^{α} f$ of order $α > 0$ with $b > a \geq 0$ are defined by

J_{a +}^{α} f (x) = \frac{1}{Γ (α)} \int_{a}^{x} {(ln \frac{x}{t})}^{α - 1} f (t) \frac{d t}{t}, a < x < b

and

J_{b -}^{α} f (x) = \frac{1}{Γ (α)} \int_{x}^{b} {(ln \frac{t}{x})}^{α - 1} f (t) \frac{d t}{t}, a < x < b,

respectively, where $Γ (α)$ is the Gamma function defined by $Γ (α) = \int_{0}^{\infty} e^{- t} t^{α - 1} d t$ (see [5]).

In recent years, many authors have studied error estimations for Hermite-Hadamard, Ostrowski and Simpson inequalities; for refinements, counterparts, generalization see [4, 6–20].

In this paper, the concept of the quasi-geometrically convex function is introduced, Hermite-Hadamard’s inequalities for GA-convex functions in fractional integral forms are established, and a new identity for Hadamard fractional integrals is defined. By using this identity, author obtains a generalization of Hadamard, Ostrowski and Simpson type inequalities for quasi-geometrically convex functions via Hadamard fractional integrals.

2 Main results

Let $f : I \subseteq (0, \infty) \to R$ be a differentiable function on $I^{\circ}$ , the interior of I, throughout this section we will take

\begin{aligned} I_{f} (x, λ, α, a, b) \\ = (1 - λ) [{ln}^{α} \frac{x}{a} + {ln}^{α} \frac{b}{x}] f (x) + λ [f (a) {ln}^{α} \frac{x}{a} + f (b) {ln}^{α} \frac{b}{x}] \\ - Γ (α + 1) [J_{x -}^{α} f (a) + J_{x +}^{α} f (b)], \end{aligned}

where $a, b \in I$ with $a < b$ , $x \in [a, b]$ , $λ \in [0, 1]$ , $α > 0$ and Γ is the Euler Gamma function.

Definition 2.1 A function $f : I \subseteq (0, \infty) \to R$ is said to be quasi-geometrically convex on I if

f (x^{t} y^{1 - t}) \leq sup {f (x), f (y)},

for any $x, y \in I$ and $t \in [0, 1]$ .

Remark 2.1 Clearly, any GA-convex and geometrically convex functions are quasi-geometrically convex functions. Furthermore, there exist quasi-geometrically convex functions which are neither GA-convex nor geometrically convex. In that context, we point out an elementary example. The function $f : (0, 4] \to R$ ,

f (x) = {\begin{cases} 1, & x \in (0, 1], \\ {(x - 2)}^{2}, & x \in [1, 4] \end{cases}

is neither GA-convex nor geometrically convex on $(0, 4]$ , but it is a quasi-geometrically convex function on $(0, 4]$ .

Proposition 2.1 If $f : I \subseteq (0, \infty) \to R$ is convex and nondecreasing, then it is quasi-geometrically convex on I.

Proof This follows from

\begin{array}{rcl} f (x^{t} y^{1 - t}) & \leq & f (t x + (1 - t) y) \\ \leq & t f (x) + (1 - t) f (y) \leq sup {f (x), f (y)}, \end{array}

for all $x, y \in I$ and $t \in [0, 1]$ . □

Proposition 2.2 If $f : I \subseteq (0, \infty) \to R$ is quasi-convex and nondecreasing, then it is quasi-geometrically convex on I. If $f : I \subseteq (0, \infty) \to R$ is quasi-geometrically convex and nonincreasing, then it is quasi-convex on I.

Proof These conclusions follows from

f (x^{t} y^{1 - t}) \leq f (t x + (1 - t) y) \leq sup {f (x), f (y)}

and

f (t x + (1 - t) y) \leq f (x^{t} y^{1 - t}) \leq sup {f (x), f (y)}

for all $x, y \in I$ and $t \in [0, 1]$ , respectively. □

Hermite-Hadamard’s inequalities can be represented for GA-convex functions in fractional integral forms as follows.

Theorem 2.1 Let $f : I \subseteq (0, \infty) \to R$ be a function such that $f \in L [a, b]$ , where $a, b \in I$ with $a < b$ . If f is a GA-convex function on $[a, b]$ , then the following inequalities for fractional integrals hold:

f (\sqrt{a b}) \leq \frac{Γ (α + 1)}{2 {(ln \frac{b}{a})}^{α}} {J_{a +}^{α} f (b) + J_{b -}^{α} f (a)} \leq \frac{f (a) + f (b)}{2}

(3)

with $α > 0$ .

Proof Since f is a GA-convex function on $[a, b]$ , we have for all $x, y \in [a, b]$ (with $t = 1 / 2$ in inequality (1)),

f (\sqrt{x y}) \leq \frac{f (x) + f (y)}{2} .

Choosing $x = a^{t} b^{1 - t}$ , $y = b^{t} a^{1 - t}$ , we get

f (\sqrt{a b}) \leq \frac{f (a^{t} b^{1 - t}) + f (b^{t} a^{1 - t})}{2} .

(4)

Multiplying both sides of (4) by $t^{α - 1}$ , then integrating the resulting inequality with respect to t over $[0, 1]$ , we obtain

\begin{array}{rcl} f (\sqrt{a b}) & \leq & \frac{α}{2} {\int_{0}^{1} f (a^{t} b^{1 - t}) d t + \int_{0}^{1} f (b^{t} a^{1 - t}) d t} \\ = & \frac{α}{2} {\int_{a}^{b} {(\frac{ln b - ln u}{ln b - ln a})}^{α - 1} f (u) \frac{d u}{u ln \frac{b}{a}} + \int_{a}^{b} {(\frac{ln u - ln a}{ln b - ln a})}^{α - 1} f (u) \frac{d u}{u ln \frac{b}{a}}} \\ = & \frac{α Γ (α)}{2 {(ln \frac{b}{a})}^{α}} {J_{a +}^{α} f (b) + J_{b -}^{α} f (a)} \\ = & \frac{Γ (α + 1)}{2 {(ln \frac{b}{a})}^{α}} {J_{a +}^{α} f (b) + J_{b -}^{α} f (a)}, \end{array}

and the first inequality is proved.

For the proof of the second inequality in (3), we first note that if f is a convex function, then for $t \in [0, 1]$ , it yields

f (a^{t} b^{1 - t}) \leq t f (a) + (1 - t) f (b)

and

f (b^{t} a^{1 - t}) \leq t f (b) + (1 - t) f (a) .

By adding these inequalities, we have

f (a^{t} b^{1 - t}) + f (b^{t} a^{1 - t}) \leq f (a) + f (b) .

(5)

Then multiplying both sides of (5) by $t^{α - 1}$ , and integrating the resulting inequality with respect to t over $[0, 1]$ , we obtain

\int_{0}^{1} f (a^{t} b^{1 - t}) t^{α - 1} d t + \int_{0}^{1} f (b^{t} a^{1 - t}) t^{α - 1} d t \leq [f (a) + f (b)] \int_{0}^{1} t^{α - 1} d t,

i.e.,

\frac{Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} {J_{a +}^{α} f (b) + J_{b -}^{α} f (a)} \leq f (a) + f (b) .

The proof is completed. □

In order to prove our main results, we need the following identity.

Lemma 2.1 Let $f : I \subseteq (0, \infty) \to R$ be a differentiable function on $I^{\circ}$ such that $f^{'} \in L [a, b]$ , where $a, b \in I$ with $a < b$ . Then for all $x \in [a, b]$ , $λ \in [0, 1]$ and $α > 0$ , we have:

\begin{array}{rcl} I_{f} (x, λ, α, a, b) & = & a {(ln \frac{x}{a})}^{α + 1} \int_{0}^{1} (t^{α} - λ) {(\frac{x}{a})}^{t} f^{'} (x^{t} a^{1 - t}) d t \\ - b {(ln \frac{b}{x})}^{α + 1} \int_{0}^{1} (t^{α} - λ) {(\frac{x}{b})}^{t} f^{'} (x^{t} b^{1 - t}) d t . \end{array}

(6)

Proof By integration by parts and twice changing the variable, for $x \neq a$ , we can state that

\begin{aligned} a ln \frac{x}{a} \int_{0}^{1} (t^{α} - λ) {(\frac{x}{a})}^{t} f^{'} (x^{t} a^{1 - t}) d t \\ = \int_{0}^{1} (t^{α} - λ) d f (x^{t} a^{1 - t}) \\ = (t^{α} - λ) f (x^{t} a^{1 - t}) |_{0}^{1} - \frac{α}{{(ln \frac{x}{a})}^{α}} \int_{a}^{x} {(ln \frac{u}{a})}^{α - 1} \frac{f (u)}{u} d u \\ = (1 - λ) f (x) + λ f (a) - \frac{Γ (α + 1)}{{(ln \frac{x}{a})}^{α}} J_{x -}^{α} f (a), \end{aligned}

(7)

and for $x \neq b$ , similarly, we get

\begin{aligned} - b ln \frac{b}{x} \int_{0}^{1} (t^{α} - λ) {(\frac{x}{b})}^{t} f^{'} (x^{t} b^{1 - t}) d t \\ = \int_{0}^{1} (t^{α} - λ) d f (x^{t} b^{1 - t}) \\ = (t^{α} - λ) f (x^{t} b^{1 - t}) |_{0}^{1} - \frac{α}{{(ln \frac{b}{x})}^{α}} \int_{x}^{b} {(ln \frac{b}{u})}^{α - 1} \frac{f (u)}{u} d u \\ = (1 - λ) f (x) + λ f (b) - \frac{Γ (α + 1)}{{(ln \frac{b}{x})}^{α}} J_{x +}^{α} f (b) . \end{aligned}

(8)

Multiplying both sides of (7) and (8) by ${(ln \frac{x}{a})}^{α}$ and ${(ln \frac{b}{x})}^{α}$ , respectively, and adding the resulting identities, we obtain the desired result. For $x = a$ and $x = b$ , the identities

I_{f} (a, λ, α; a, b) = b {(ln \frac{b}{a})}^{α + 1} \int_{0}^{1} (t^{α} - λ) {(\frac{a}{b})}^{t} f^{'} (a^{t} b^{1 - t}) d t,

and

I_{f} (b, λ, α; a, b) = a {(ln \frac{b}{a})}^{α + 1} \int_{0}^{1} (t^{α} - λ) {(\frac{b}{a})}^{t} f^{'} (b^{t} a^{1 - t}),

can be proved respectively easily by performing an integration by parts in the integrals from the right-hand side and changing the variable. □

Theorem 2.2 Let $f : I \subset (0, \infty) \to R$ be a differentiable function on $I^{\circ}$ such that $f^{'} \in L [a, b]$ , where $a, b \in I^{\circ}$ with $a < b$ . If ${| f^{'} |}^{q}$ is quasi-geometrically convex on $[a, b]$ for some fixed $q \geq 1$ , $x \in [a, b]$ , $λ \in [0, 1]$ and $α > 0$ , then the following inequality for fractional integrals holds:

\begin{aligned} | I_{f} (x, λ, α, a, b) | \\ \leq A_{1}^{1 - \frac{1}{q}} (α, λ) {a {(ln \frac{x}{a})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} B_{1}^{\frac{1}{q}} (x, α, λ, q) \\ + b {(ln \frac{b}{x})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} B_{2}^{\frac{1}{q}} (x, α, λ, q)}, \end{aligned}

(9)

where

\begin{matrix} A_{1} (α, λ) = \frac{2 α λ^{1 + \frac{1}{α}} + 1}{α + 1} - λ, \\ B_{1} (x, α, λ, q) = \int_{0}^{1} | t^{α} - λ | {(\frac{x}{a})}^{q t} d t, \\ B_{2} (x, α, λ, q) = \int_{0}^{1} | t^{α} - λ | {(\frac{x}{b})}^{q t} d t . \end{matrix}

Proof Since $| f^{'} |^{q}$ is quasi-geometrically convex on $[a, b]$ , for all $t \in [0, 1]$ ,

| f^{'} (x^{t} a^{1 - t}) |^{q} \leq sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}}

and

| f^{'} (x^{t} b^{1 - t}) |^{q} \leq sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}} .

Hence, using Lemma 2.1 and power mean inequality, we get

\begin{aligned} | I_{f} (x, λ, α, a, b) | \\ \leq a {(ln \frac{x}{a})}^{α + 1} {(\int_{0}^{1} | t^{α} - λ | d t)}^{1 - \frac{1}{q}} {(\int_{0}^{1} | t^{α} - λ | {(\frac{x}{a})}^{q t} sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}} d t)}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{α + 1} {(\int_{0}^{1} | t^{α} - λ | d t)}^{1 - \frac{1}{q}} {(\int_{0}^{1} | t^{α} - λ | {(\frac{x}{b})}^{q t} sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}} d t)}^{\frac{1}{q}}, \\ | I_{f} (x, λ, α, a, b) | \leq {(\int_{0}^{1} | t^{α} - λ | d t)}^{1 - \frac{1}{q}} \\ \times {a {(ln \frac{x}{a})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} {(\int_{0}^{1} | t^{α} - λ | {(\frac{x}{a})}^{q t} d t)}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} {(\int_{0}^{1} | t^{α} - λ | {(\frac{x}{b})}^{q t} d t)}^{\frac{1}{q}}} \\ \leq A_{1}^{1 - \frac{1}{q}} (α, λ) {a {(ln \frac{x}{a})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} B_{1}^{\frac{1}{q}} (x, α, λ, q) \\ + b {(ln \frac{b}{x})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} B_{2}^{\frac{1}{q}} (x, α, λ, q)}, \end{aligned}

which completes the proof. □

Corollary 2.1 Under the assumptions of Theorem 2.2 with $q = 1$ , inequality (9) reduces to the following inequality:

\begin{array}{rcl} | I_{f} (x, λ, α, a, b) | & \leq & {a {(ln \frac{x}{a})}^{α + 1} B_{1} (x, α, λ, 1) sup {| f^{'} (x) |, | f^{'} (a) |} \\ + b {(ln \frac{b}{x})}^{α + 1} B_{2} (x, α, λ, 1) sup {| f^{'} (x) |, | f^{'} (b) |}} . \end{array}

Corollary 2.2 Under the assumptions of Theorem 2.2 with $α = 1$ , inequality (9) reduces to the following inequality:

\begin{aligned} {(ln \frac{b}{a})}^{- 1} | I_{f} (x, λ, α, a, b) | \\ \leq | (1 - λ) f (x) + λ [\frac{f (a) ln \frac{x}{a} + f (b) ln \frac{b}{x}}{ln \frac{b}{a}}] - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq {(ln \frac{b}{a})}^{- 1} {(\frac{2 λ^{2} - 2 λ + 1}{2})}^{1 - \frac{1}{q}} {a {(ln \frac{x}{a})}^{2} B_{1}^{\frac{1}{q}} (x, 1, λ, q) {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{2} B_{2}^{\frac{1}{q}} (x, 1, λ, q) {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}}}, \end{aligned}

where

\begin{matrix} B_{1} (x, 1, λ, q) = h_{λ} ({(\frac{x}{a})}^{q}), B_{2} (x, 1, λ, q) = h_{λ} ({(\frac{x}{b})}^{q}), \\ h (u, λ) = \frac{2 u^{λ} - u - 1}{{(ln u)}^{2}} + \frac{(1 - λ) u - λ}{ln u}, u \in (0, \infty) ∖ {1}, \end{matrix}

(10)

specially for $x = \sqrt{a b}$ , we get

\begin{aligned} | (1 - λ) f (\sqrt{a b}) + λ (\frac{f (a) + f (b)}{2}) - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{ln \frac{b}{a}}{4} {(\frac{2 λ^{2} - 2 λ + 1}{2})}^{1 - \frac{1}{q}} {a h^{\frac{1}{q}} ({(\frac{b}{a})}^{\frac{q}{2}}, λ) {(sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} \\ + b h^{\frac{1}{q}} ({(\frac{a}{b})}^{\frac{q}{2}}, λ) {(sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}}} . \end{aligned}

(11)

Corollary 2.3 In Theorem 2.2,

1.
If we take $x = \sqrt{a b}$ , $λ = \frac{1}{3}$ , then we get the following Simpson-type inequality for fractional integrals:
$\begin{aligned} | \frac{1}{6} [f (a) + 4 f (\sqrt{a b}) + f (b)] - \frac{2^{α - 1} Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{ln \frac{b}{a}}{4} A_{1}^{1 - \frac{1}{q}} (α, \frac{1}{3}) {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} B_{1}^{\frac{1}{q}} (\sqrt{a b}, α, \frac{1}{3}, q) \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} B_{2}^{\frac{1}{q}} (\sqrt{a b}, α, \frac{1}{3}, q)}, \end{aligned}$

specially for $α = 1$ , we get

\begin{aligned} | \frac{1}{6} [f (a) + 4 f (\sqrt{a b}) + f (b)] - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{ln \frac{b}{a}}{4} {(\frac{5}{18})}^{1 - \frac{1}{q}} {a {[sup {| f^{'} (\sqrt{a b}) |, | f^{'} (a) |}]}^{\frac{1}{q}} h^{\frac{1}{q}} ({(\frac{b}{a})}^{\frac{q}{2}}, \frac{1}{3}) \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} h^{\frac{1}{q}} ({(\frac{a}{b})}^{\frac{q}{2}}, \frac{1}{3})}, \end{aligned}

where h is defined as in (10).

Remark 2.2

1.
If we take $x = \sqrt{a b}$ , $λ = 0$ , then we get the following midpoint- type inequality for fractional integrals:
$\begin{aligned} | f (\sqrt{a b}) - \frac{2^{α - 1} Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{ln \frac{b}{a}}{4} {(\frac{1}{α + 1})}^{1 - \frac{1}{q}} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} B_{1}^{\frac{1}{q}} (\sqrt{a b}, 1, 0, q) \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} B_{2}^{\frac{1}{q}} (\sqrt{a b}, 1, 0, q)}, \end{aligned}$

specially for $α = 1$ , we get

\begin{aligned} | f (\sqrt{a b}) - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{2^{\frac{1}{q}} ln \frac{b}{a}}{8} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} h^{\frac{1}{q}} ({(\frac{b}{a})}^{\frac{q}{2}}, 0) \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} h^{\frac{1}{q}} ({(\frac{a}{b})}^{\frac{q}{2}}, 0)}, \end{aligned}

where h is defined as in (10).

2.
If we take $x = \sqrt{a b}$ , $λ = 1$ , then we get the following trapezoid-type inequality for fractional integrals:
$\begin{aligned} | \frac{f (a) + f (b)}{2} - \frac{2^{α - 1} Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{ln \frac{b}{a}}{4} {(\frac{1}{α + 1})}^{1 - \frac{1}{q}} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} B_{1}^{\frac{1}{q}} (\sqrt{a b}, α, 1, q) \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} B_{2}^{\frac{1}{q}} (\sqrt{a b}, α, 1, q)}, \end{aligned}$

specially for $α = 1$ , we get

\begin{aligned} | \frac{f (a) + f (b)}{2} - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{2^{\frac{1}{q}} ln \frac{b}{a}}{8} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} h^{\frac{1}{q}} ({(\frac{b}{a})}^{\frac{q}{2}}, 1) \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} h^{\frac{1}{q}} ({(\frac{a}{b})}^{\frac{q}{2}}, 1)}, \end{aligned}

where h is defined as in (10).

Corollary 2.4 Let the assumptions of Theorem 2.2 hold. If $| f^{'} (x) | \leq M$ for all $x \in [a, b]$ and $λ = 0$ , then we get the following Ostrowski-type inequality for fractional integrals from inequality (9):

\begin{aligned} | [{(ln \frac{x}{a})}^{α} + {(ln \frac{b}{x})}^{α}] f (x) - Γ (α + 1) [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{M}{{(α + 1)}^{1 - \frac{1}{q}}} [a {(ln \frac{x}{a})}^{α + 1} B_{1}^{\frac{1}{q}} (x, α, 0, q) + b {(ln \frac{b}{x})}^{α + 1} B_{2}^{\frac{1}{q}} (x, α, 0, q)] . \end{aligned}

Theorem 2.3 Let $f : I \subset (0, \infty) \to R$ be a differentiable function on $I^{\circ}$ such that $f^{'} \in L [a, b]$ , where $a, b \in I^{\circ}$ with $a < b$ . If ${| f^{'} |}^{q}$ is quasi-geometrically convex on $[a, b]$ for some fixed $q > 1$ , $x \in [a, b]$ , $λ \in [0, 1]$ and $α > 0$ , then the following inequality for fractional integrals holds:

\begin{aligned} | I_{f} (x, λ, α, a, b) | \\ \leq A_{2}^{\frac{1}{p}} (α, λ, p) {a {(ln \frac{x}{a})}^{α + \frac{1}{p}} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} {(\frac{x^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{α + \frac{1}{p}} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} {(\frac{b^{q} - x^{q}}{q})}^{\frac{1}{q}}}, \end{aligned}

(12)

where

\begin{aligned} A_{2} (α, λ, p) \\ = {\begin{cases} \frac{1}{α p + 1}, & λ = 0, \\ \frac{λ^{\frac{α p + 1}{α}}}{α} {β (\frac{1}{α}, p + 1) + \frac{{(1 - λ)}^{p + 1}}{p + 1} \\ \times_{2} F_{1} (\frac{1}{α} + p + 1, p + 1, p + 2; 1 - λ)}, & 0 < λ < 1, \\ \frac{1}{α} β (p + 1, \frac{1}{α}), & λ = 1, \end{cases} \end{aligned}

${}_{2}F_{1}$ is hypergeometric function defined by

{}_{2}F_{1} (a, b; c; z) = \frac{1}{β (b, c - b)} \int_{0}^{1} t^{b - 1} {(1 - t)}^{c - b - 1} {(1 - z t)}^{- a} d t, c > b > 0, | z | < 1 (see [21]),

and $\frac{1}{p} + \frac{1}{q} = 1$ .

Proof Using Lemma 2.1, the Hölder inequality and quasi-geometrical convexity of ${| f^{'} |}^{q}$ , we get

\begin{aligned} | I_{f} (x, λ, α, a, b) | \\ \leq a {(ln \frac{x}{a})}^{α + 1} {(\int_{0}^{1} | t^{α} - λ |^{p} d t)}^{\frac{1}{p}} {(\int_{0}^{1} {(\frac{x}{a})}^{q t} sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}} d t)}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{α + 1} {(\int_{0}^{1} | t^{α} - λ |^{p} d t)}^{\frac{1}{p}} {(\int_{0}^{1} {(\frac{x}{b})}^{q t} sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}} d t)}^{\frac{1}{q}}, \\ | I_{f} (x, λ, α, a, b) | \leq {(\int_{0}^{1} | t^{α} - λ |^{p} d t)}^{\frac{1}{p}} \\ \times {a {(ln \frac{x}{a})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} {(\int_{0}^{1} {(\frac{x}{a})}^{q t} d t)}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{α + 1} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} {(\int_{0}^{1} {(\frac{x}{b})}^{q t} d t)}^{\frac{1}{q}}} \\ \leq A_{2}^{\frac{1}{p}} (α, λ, p) {a {(ln \frac{x}{a})}^{α + 1 - \frac{1}{q}} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} {(\frac{x^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{α + 1 - \frac{1}{q}} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} {(\frac{b^{q} - x^{q}}{q})}^{\frac{1}{q}}}, \end{aligned}

here, it is seen by a simple computation that

\begin{array}{rcl} A_{2} (α, λ, p) & = & \int_{0}^{1} | t^{α} - λ |^{p} d t \\ = & {\begin{cases} \frac{1}{α p + 1}, & λ = 0, \\ \frac{λ^{\frac{α p + 1}{α}}}{α} {β (\frac{1}{α}, p + 1) + \frac{{(1 - λ)}^{p + 1}}{p + 1} \\ \times_{2} F_{1} (\frac{1}{α} + p + 1, p + 1, 2 + p; 1 - λ)}, & 0 < λ < 1, \\ \frac{1}{α} β (p + 1, \frac{1}{α}), & λ = 1 . \end{cases} \end{array}

Hence, the proof is completed. □

Corollary 2.5 Under the assumptions of Theorem 2.3 with $α = 1$ , inequality (12) reduces to the following inequality:

\begin{aligned} | (1 - λ) f (x) + λ [\frac{f (a) ln \frac{x}{a} + f (b) ln \frac{b}{x}}{ln \frac{b}{a}}] - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq {(ln \frac{b}{a})}^{- 1} {(\frac{λ^{p + 1} + {(1 - λ)}^{p + 1}}{p + 1})}^{\frac{1}{p}} \\ \times {a {(ln \frac{x}{a})}^{1 + \frac{1}{p}} {(sup {| f^{'} (x) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} {(\frac{x^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {(ln \frac{b}{x})}^{1 + \frac{1}{p}} {(sup {| f^{'} (x) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} {(\frac{b^{q} - x^{q}}{q})}^{\frac{1}{q}}}, \end{aligned}

specially for $x = \sqrt{a b}$ , we get

\begin{aligned} | (1 - λ) f (\sqrt{a b}) + λ (\frac{f (a) + f (b)}{2}) - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a} (λ^{p + 1} + {(1 - λ)}^{p + 1})}{2 (p + 1)})}^{\frac{1}{p}} {a {(sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}})}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {(sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}})}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}} . \end{aligned}

(13)

Corollary 2.6 In Theorem 2.3,

1.
If we take $x = \sqrt{a b}$ , $λ = \frac{1}{3}$ , then we get the following Simpson-type inequality for fractional integrals:
$\begin{aligned} | \frac{1}{6} [f (a) + 4 f (\sqrt{a b}) + f (b)] - \frac{2^{α - 1} Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a} (1 + 2^{p + 1})}{3^{p + 1} (p + 1) 2})}^{\frac{1}{p}} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}}, \end{aligned}$

specially for $α = 1$ , we get

\begin{aligned} | \frac{1}{6} [f (a) + 4 f (\sqrt{a b}) + f (b)] - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a} (1 + 2^{p + 1})}{3^{p + 1} (p + 1) 2})}^{\frac{1}{p}} \\ \times {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}} . \end{aligned}

Remark 2.3

1.
If we take $x = \sqrt{a b}$ , $λ = 0$ , then we get the following midpoint- type inequality for fractional integrals:
$\begin{aligned} | f (\sqrt{a b}) - \frac{2^{α - 1} Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a}}{2 (α p + 1)})}^{\frac{1}{p}} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}}, \end{aligned}$

specially for $α = 1$ , we get

\begin{aligned} | f (\sqrt{a b}) - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a}}{2 (p + 1)})}^{\frac{1}{p}} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}} . \end{aligned}

2.
If we take $x = \sqrt{a b}$ , $λ = 1$ , then we get the following trapezoid-type inequality for fractional integrals $\frac{1}{α} β (p + 1, \frac{1}{α})$ :
$\begin{aligned} | \frac{f (a) + f (b)}{2} - \frac{2^{α - 1} Γ (α + 1)}{{(ln \frac{b}{a})}^{α}} [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a} β (p + 1, \frac{1}{α})}{2 α})}^{\frac{1}{p}} \\ \times {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}}, \end{aligned}$

specially for $α = 1$ , we get

\begin{aligned} | \frac{f (a) + f (b)}{2} - \frac{1}{ln \frac{b}{a}} \int_{a}^{b} \frac{f (u)}{u} d u | \\ \leq \frac{1}{2} {(\frac{ln \frac{b}{a}}{2 (p + 1)})}^{\frac{1}{p}} {a {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (a) |^{q}}]}^{\frac{1}{q}} {(\frac{{\sqrt{a b}}^{q} - a^{q}}{q})}^{\frac{1}{q}} \\ + b {[sup {| f^{'} (\sqrt{a b}) |^{q}, | f^{'} (b) |^{q}}]}^{\frac{1}{q}} {(\frac{b^{q} - {\sqrt{a b}}^{q}}{q})}^{\frac{1}{q}}} . \end{aligned}

Corollary 2.7 Let the assumptions of Theorem 2.3 hold. If $| f^{'} (x) | \leq M$ for all $x \in [a, b]$ and $λ = 0$ , then we get the following Ostrowski-type inequality for fractional integrals from inequality (12):

\begin{aligned} | [{(ln \frac{x}{a})}^{α} + {(ln \frac{b}{x})}^{α}] f (x) - Γ (α + 1) [J_{\sqrt{a b} -}^{α} f (a) + J_{\sqrt{a b} +}^{α} f (b)] | \\ \leq \frac{M}{{(α p + 1)}^{\frac{1}{p}}} [a {(ln \frac{x}{a})}^{α + \frac{1}{p}} {(\frac{x^{q} - a^{q}}{q})}^{\frac{1}{q}} + b {(ln \frac{b}{x})}^{α + \frac{1}{p}} {(\frac{b^{q} - x^{q}}{q})}^{\frac{1}{q}}] . \end{aligned}

3 Application to special means

Let us recall the following special means of two nonnegative numbers a, b with $b > a$ :

1.
The arithmetic mean
$A = A (a, b) : = \frac{a + b}{2} .$
2.
The geometric mean
$G = G (a, b) : = \sqrt{a b} .$
3.
The logarithmic mean
$L = L (a, b) : = \frac{b - a}{ln b - ln a} .$
4.
The p-logarithmic mean
$L_{p} = L_{p} (a, b) : = {(\frac{b^{p + 1} - a^{p + 1}}{(p + 1) (b - a)})}^{\frac{1}{p}}, p \in R ∖ {- 1, 0} .$

Proposition 3.1 For $b > a > 0$ , $n > 0$ and $q \geq 1$ , we have

\begin{aligned} | (1 - λ) G^{n + 1} (a, b) + λ A (a^{n + 1}, b^{n + 1}) - (n + 1) L (a, b) L_{n}^{n} (a, b) | \\ \leq \frac{(n + 1) ln \frac{b}{a}}{4} {(\frac{2 λ^{2} - 2 λ + 1}{2})}^{1 - \frac{1}{q}} {a G^{n} (a, b) h^{\frac{1}{q}} ({(\frac{b}{a})}^{\frac{q}{2}}, λ) \\ + b^{n + 1} h^{\frac{1}{q}} ({(\frac{a}{b})}^{\frac{q}{2}}, λ)}, \end{aligned}

where h is defined as in (10).

Proof Let $f (x) = \frac{x^{n + 1}}{n + 1}$ , $x > 0$ , $n > 0$ and $q \geq 1$ . Then the function $| f^{'} (x) |^{q} = x^{n q}$ is quasi-geometrically convex on $(0, \infty)$ . Thus, by inequality (11), Proposition 3.1 is proved. □

Proposition 3.2 For $b > a > 0$ , $n > 0$ and $q > 1$ , we have

\begin{aligned} | (1 - λ) G^{n + 1} (a, b) + λ A (a^{n + 1}, b^{n + 1}) - (n + 1) L (a, b) L_{n}^{n} (a, b) | \\ \leq \frac{n + 1}{2} {(\frac{ln \frac{b}{a} (λ^{p + 1} + {(1 - λ)}^{p + 1})}{2 (p + 1)})}^{\frac{1}{p}} {a G^{n} (a, b) {(\frac{G^{q} (a, b) - a^{q}}{q})}^{\frac{1}{q}} \\ + b^{n + 1} {(\frac{b^{q} - G^{q} (a, b)}{q})}^{\frac{1}{q}}} . \end{aligned}

Proof Let $f (x) = \frac{x^{n + 1}}{n + 1}$ , $x > 0$ , $n > 0$ and $q > 1$ . Then the function $| f^{'} (x) |^{q} = x^{n q}$ is quasi-geometrically convex on $(0, \infty)$ . Thus, by inequality (13), Proposition 3.2 is proved. □

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Department of Mathematics, Faculty of Sciences and Arts, Giresun University, Giresun, 28100, Turkey
İmdat İşcan

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İşcan, İ. New general integral inequalities for quasi-geometrically convex functions via fractional integrals. J Inequal Appl 2013, 491 (2013). https://doi.org/10.1186/1029-242X-2013-491

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Received: 04 August 2013
Accepted: 09 September 2013
Published: 07 November 2013
DOI: https://doi.org/10.1186/1029-242X-2013-491

New general integral inequalities for quasi-geometrically convex functions via fractional integrals

Abstract

1 Introduction

2 Main results

3 Application to special means

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