On the refinements of the Hermite-Hadamard inequality

In this paper, we present some refinements of the classical Hermite-Hadamard integral inequality for convex functions. Further, we give the concept of n-exponential convexity and log-convexity of the functions associated with the linear functionals defined by these inequalities and prove monotonicity property of the generalized Cauchy means obtained via these functionals. Finally, we give several examples of the families of functions for which the results can be applied.

MSC: 26D15.

One of the most well-known inequalities in mathematics for convex functions is so called Hermite-Hadamard integral inequality (see [[1], p.137])

provided that for an interval $[a,b]\subseteq \mathbb{R}$, $f:[a,b]\to \mathbb{R}$ is a convex function. If the function f is concave, then (1) holds in the reverse direction. It gives an estimate from below and above of the mean value of a convex function. These inequalities for convex functions play an important role in nonlinear analysis. In recent years there have been many extensions, generalizations and similar type results of the inequalities in (1) (see [2–4]). These classical inequalities have been improved and generalized in many ways and applied for special means including Stolarsky-type means, logarithmic and p-logarithmic means. Also, many interesting applications of Hermite-Hadamard inequality can be found in [1].

In this paper, we present some refinements of the first Hermite-Hadamard integral inequality. Further, we study the n-exponential convexity and log-convexity of the functions associated with the linear functionals defined as differences of the left-hand and the right-hand sides of these inequalities. We also prove monotonicity property of the generalized Cauchy means obtained via these functionals. Finally, we give several examples of the families of functions for which the obtained results can be applied.

We shall start with the following refinement of the first Hermite-Hadamard inequality for differentiable convex functions.

Theorem 2.1 Let$a,b\in \mathbb{R}$with$a<b$and$f:[a,b]\to \mathbb{R}$be a differentiable convex function. Then the function

is increasing on$[a,b]$and for all$x,y\in [a,b]$such that$x\le y$, we have

Proof We have

where $\frac{b-x}{b-a}\ge 0$, as $a<b$ and $x\in [a,b]$. If we prove that

then $H(x)$ will be increasing on $[a,b]$.

For $x\ge a$, we have $x-\frac{2bx-x^2-a^2}{2(b-a)}\ge 0$. Since f is a differentiable convex function defined on $[a,b]$, $f^{\mathrm{\prime }}$ is increasing on $[a,b]$, and so (4) holds, which in turn implies that $H^{\mathrm{\prime }}(x)\ge 0$, showing that $H(x)$ is increasing on $[a,b]$.

Now, as $H(x)$ is increasing on $[a,b]$, for any $x,y\in [a,b]$ such that $a\le x\le y\le b$, we have

At $x=a$ and at $x=b$, (2) gives $H(a)=0$ and $H(b)=\frac{1}{b-a}{\int }_a^{b}f(t)dt-f(\frac{a+b}{2})$ respectively. By using these values of $H(a)$ and $H(b)$ in (5), we have (3). □

Remark 2.2 If f is strictly convex, then $H(x)$ is strictly increasing on $[a,b)$ and strict inequalities hold in (3).

The second main result is another refinement of the first Hermite-Hadamard inequality for differentiable convex functions.

Theorem 2.3 Let$a,b\in \mathbb{R}$with$a<b$and$f:[a,b]\to \mathbb{R}$be a differentiable convex function. Then the function

is decreasing on$[a,b]$and for any$x,y\in [a,b]$such that$x\le y$, we have

Proof We have

where $\frac{x-a}{b-a}\ge 0$, as $a<b$ and $x\in [a,b]$. If we prove that

then $\overline{H}(x)$ will be decreasing on $[a,b]$.

For $x\le b$, we have $\frac{x^2+b^2-2ax}{2(b-a)}-x\ge 0$. Since f is a differentiable convex function defined on $[a,b]$, $f^{\mathrm{\prime }}$ is increasing on $[a,b]$, and so (8) holds, which in turn implies that ${\overline{H}}^{\mathrm{\prime }}(x)\le 0$, showing that $\overline{H}(x)$ is decreasing on $[a,b]$.

Now, as $\overline{H}(x)$ is decreasing on $[a,b]$, for any $x,y\in [a,b]$ such that $a\le x\le y\le b$, we have

At $x=a$ and at $x=b$, (6) gives $\overline{H}(a)=\frac{1}{b-a}{\int }_a^{b}f(t)dt-f(\frac{a+b}{2})$ and $\overline{H}(b)=0$ respectively. By using these values of $\overline{H}(a)$ and $\overline{H}(b)$ in (9), we have (7). □

Remark 2.4 If f is strictly convex, then $\overline{H}(x)$ is strictly decreasing on $(a,b]$ and strict inequalities hold in (7).

Let us observe the inequalities (3) and (7). Motivated by them, we define two functionals

(10)

(11)

where $x,y\in [a,b]$ and the functions H and $\overline{H}$ are as in (2) and (6) respectively. If f is a differentiable convex function defined on $[a,b]$, then Theorems 2.1 and 2.3 imply that ${\mathrm{\Phi }}_i(x,y;f)\ge 0$, $i=1,2$. Now, we give mean value theorems for the functionals ${\mathrm{\Phi }}_i$, $i=1,2$.

Theorem 2.5 Let$f\in C^2[a,b]$and$x,y\in [a,b]$be such that$x\le y$. Let${\mathrm{\Phi }}_1$and${\mathrm{\Phi }}_2$be linear functionals defined as in (10) and (11). Then there exists${\xi }_1,{\xi }_2\in [a,b]$such that

where$f_0(z)=z^2$.

Proof Analogous to the proof of Theorem 2.4 in [5]. □

Theorem 2.6 Let$f,g\in C^2[a,b]$and$x,y\in [a,b]$be such that$x\le y$, where$g^{″}(x)\ne 0$for every$x\in [a,b]$. Let${\mathrm{\Phi }}_1$and${\mathrm{\Phi }}_2$be linear functionals defined as in (10) and (11). If${\mathrm{\Phi }}_1$and${\mathrm{\Phi }}_2$are positive, then there exists${\xi }_1,{\xi }_2\in [a,b]$such that

Proof Analogous to the proof of Theorem 2.6 in [5]. □

Remark 2.7 If the inverse of the function $\frac{f^{″}}{g^{″}}$ exists, then (13) gives

We begin this section by recollecting the definitions and properties which are going to be explored here and also some useful characterizations of these properties. Throughout the paper, I is an open interval in $\mathbb{R}$.

Definition 1 A function $h:I\to \mathbb{R}$ is n-exponentially convex in the Jensen sense on I if

holds for every ${\alpha }_i\in \mathbb{R}$ and $x_i\in I$, $i=1,\dots ,n$ (see [5]).

Definition 2 A function $h:I\to \mathbb{R}$ is n-exponentially convex on I if it is n-exponentially convex in the Jensen sense and continuous on I.

Remark 3.1 From the above definition it is clear that 1-exponentially convex functions in the Jensen sense are nonnegative functions. Also, n-exponentially convex functions in the Jensen sense are k-exponentially convex functions in the Jensen sense for all $k\in \mathbb{N}$, $k\le n$.

By definition of positive semi-definite matrices and some basic linear algebra, we have the following proposition.

Proposition 3.2 If h is n-exponentially convex in the Jensen sense, then the matrix${[h(\frac{x_i+x_j}{2})]}_{i,j=1}^k$is a positive semi-definite matrix for all$k\in \mathbb{N}$, $k\le n$. Particularly,

Definition 3 A function $h:I\to \mathbb{R}$ is exponentially convex in the Jensen sense if it is n-exponentially convex in the Jensen sense for all $n\in \mathbb{N}$.

Definition 4 A function $h:I\to \mathbb{R}$ is exponentially convex if it is exponentially convex in the Jensen sense and continuous.

Lemma 3.3 A function$h:I\to (0,\mathrm{\infty })$is log-convex in the Jensen sense, that is, for every$x,y\in I$,

holds if and only if the relation

holds for every$\alpha ,\beta \in \mathbb{R}$and$x,y\in I$.

Remark 3.4 It follows that a function is log-convex in the Jensen sense if and only if it is 2-exponentially convex in the Jensen sense. Also, by using the basic convexity theory, a function is log-convex if and only if it is 2-exponentially convex.

The following result will be useful further (see [[1], p.2]).

Lemma 3.5 If f is a convex function defined on an interval I and$x_1\le y_1$, $x_2\le y_2$, $x_1\ne x_2$, $y_1\ne y_2$, then the following inequality is valid

If the function f is concave, the inequality reverses.

Definition 5 The second order divided difference of a function $f:[a,b]\to \mathbb{R}$ at mutually distinct points $y_0,y_1,y_2\in [a,b]$ is defined recursively by

(15)

Remark 3.6 The value $[y_0,y_1,y_2;f]$ is independent of the order of the points $y_0$, $y_1$ and $y_2$. This definition may be extended to include the case in which some or all the points coincide (see [[1], p.16]). Namely, taking the limit $y_1\to y_0$ in (15), we get

provided that $f^{\prime }$ exists; and furthermore, taking the limits $y_i\to y_0$, $i=1,2$, in (15), we get

provided that $f^{″}$ exists.

The following definition of a real valued convex function is characterized by second order divided difference (see [[1], p.15]).

Definition 6 A function $f:[a,b]\to \mathbb{R}$ is said to be convex if and only if for all choices of three distinct points $y_0,y_1,y_2\in [a,b]$, $[y_0,y_1,y_2;f]\ge 0$.

Next, we study the n-exponential convexity and log-convexity of the functions associated with the linear functionals ${\mathrm{\Phi }}_i$ ($i=1,2$) defined in (10) and (11).

Theorem 3.7 Let$\mathrm{\Omega }=\{f_s:s\in I\subseteq \mathbb{R}\}$be a family of differentiable functions defined on$[a,b]$such that the function$s\mapsto [y_0,y_1,y_2;f_s]$is n-exponentially convex in the Jensen sense on I for every three mutually distinct points$y_0,y_1,y_2\in [a,b]$. Let${\mathrm{\Phi }}_i$ ($i=1,2$) be linear functionals defined as in (10) and (11). Then the following statements hold.

(i) The function$s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$is n-exponentially convex in the Jensen sense on I.

(ii) If the function$s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$is continuous on I, then it is n-exponentially convex on I.

Proof The idea of the proof is the same as in [5].

(i) Let ${\alpha }_j\in \mathbb{R}$ ($j=1,\dots ,n$) and consider the function

where $s_j\in I$ and $f_{\frac{s_j+s_k}{2}}\in \mathrm{\Omega }$. Then

and since $[y_0,y_1,y_2;f_{\frac{s_j+s_k}{2}}]$ is n-exponentially convex in the Jensen sense on I by assumption, it follows that

And so by using Definition 6, we conclude that g is a convex function. Hence

which is equivalent to

and so we conclude that the function $s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$ is n-exponentially convex in the Jensen sense on I.

(ii) If the function $s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$ is continuous on I, then from (i) and by Definition 2 it follows that it is n-exponentially convex on I.

 □

Corollary 3.8 Let$\mathrm{\Omega }=\{f_s:s\in I\subseteq \mathbb{R}\}$be a family of differentiable functions defined on$[a,b]$such that the function$s\mapsto [y_0,y_1,y_2;f_s]$is exponentially convex in the Jensen sense on I for every three mutually distinct points$y_0,y_1,y_2\in [a,b]$. Let${\mathrm{\Phi }}_i$ ($i=1,2$) be linear functionals defined as in (10) and (11). Then the following statements hold.

(i) The function$s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$is exponentially convex in the Jensen sense on I.

(ii) If the function$s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$is continuous on I, then it is exponentially convex on I.

Corollary 3.9 Let$\mathrm{\Omega }=\{f_s:s\in I\subseteq \mathbb{R}\}$be a family of differentiable functions defined on$[a,b]$such that the function$s\mapsto [y_0,y_1,y_2;f_s]$is 2-exponentially convex in the Jensen sense on I for every three mutually distinct points$y_0,y_1,y_2\in [a,b]$. Let${\mathrm{\Phi }}_i$ ($i=1,2$) be linear functionals defined as in (10) and (11). Further, assume${\mathrm{\Phi }}_i(x,y;f_s)$ ($i=1,2$) is strictly positive for$f_s\in \mathrm{\Omega }$. Then the following statements hold:

(i) If the function$s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$is continuous on I, then it is 2-exponentially convex on I and so, it is log-convex.

(ii) If the function$s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$is differentiable on I, then for every$s,q,u,v\in I$such that$s\le u$and$q\le v$, we have

where

for$f_s,f_q\in \mathrm{\Omega }$.

Proof The idea of the proof is the same as in [5].

(i) The claim is an immediate consequence of Theorem 3.7 and Remark 3.4.

(ii) Since by (i) the function $s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$ is log-convex on I, that is, the function $s\mapsto log{\mathrm{\Phi }}_i(x,y;f_s)$ is convex on I. Applying Lemma 3.5 with setting $f(z)=log{\mathrm{\Phi }}_i(x,y;f_z)$ ($i=1,2$), we get

for $s\le u$, $q\le v$, $s\ne q,u\ne v$; and therefore conclude that

If $s=q$, we consider the limit when $q\to s$ in (18) and conclude that

The case $u=v$ can be treated similarly.

 □

Remark 3.10 Note that the results from Theorem 3.7, Corollary 3.8 and Corollary 3.9 still hold when two of the points $y_0,y_1,y_2\in [a,b]$ coincide, say $y_1=y_0$, for a family of differentiable functions $f_s$ such that the function $s\mapsto [y_0,y_1,y_2;f_s]$ is n-exponentially convex in the Jensen sense (exponentially convex in the Jensen sense, log-convex in the Jensen sense on I); and furthermore, they still hold when all three points coincide for a family of twice differentiable functions with the same property. The proofs are obtained by recalling Remark 3.6 and by using suitable characterizations of convexity.

In this section, we present several families of functions which fulfill the conditions of Theorem 3.7, Corollary 3.8 and Corollary 3.9 (Remark 3.10). In this way, we can construct large families of functions which are exponentially convex.

Example 4.1 Consider the family of functions

defined by

We have $\frac{d^2}{d{x}^2}{g}_s(x)=e^{sx}>0$ which shows that $g_s$ is convex on $\mathbb{R}$ for every $s\in \mathbb{R}$ and $s\mapsto \frac{d^2}{d{x}^2}{g}_s(x)$ is exponentially convex by Example 4.1 given in [6]. From [6], we then also have that $s\mapsto [y_0,y_1,y_2;g_s]$ is exponentially convex and so $s\mapsto [y_0,y_1,y_2;g_s]$ is exponentially convex in Jensen sense. Now, by using Corollary 3.8, we have $s\mapsto {\mathrm{\Phi }}_i(x,y;g_s)$ ($i=1,2$) are exponentially convex in Jensen sense. Since these mappings are continuous (although the mapping $s\mapsto g_s$ is not continuous for $s=0$), $s\mapsto {\mathrm{\Phi }}_i(x,y;g_s)$ ($i=1,2$) are exponentially convex.

For this family of functions, by taking $\mathrm{\Omega }={\mathrm{\Omega }}_1$ in (17), ${\mathrm{\Xi }}_{s,q;1}^i:={\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_1)$ ($i=1,2$) are of the form

where

By using Theorem 2.6, it can be seen that

satisfy $min\{a,b\}\le M_{s,q}(x,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_1)\le max\{a,b\}$, showing that $M_{s,q}(x,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_1)$ ($i=1,2$) are means.

Example 4.2 Consider the family of functions

defined by

Here, $\frac{d^2}{d{x}^2}{f}_s(x)=x^{s-2}=e^{(s-2)lnx}>0$ which shows that $f_s$ is convex for $x>0$ and $s\mapsto \frac{d^2}{d{x}^2}{f}_s(x)$ is exponentially convex by Example 4.2 given in [6]. From [6], we have $s\mapsto [y_0,y_1,y_2;f_s]$ is exponentially convex. Arguing as in Example 4.1, we have $s\mapsto {\mathrm{\Phi }}_i(x,y;f_s)$ ($i=1,2$) are exponentially convex.

By taking $\mathrm{\Omega }={\mathrm{\Omega }}_2$ in (17), ${\mathrm{\Xi }}_{s,q;2}^i:={\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_2)$ ($i=1,2$) for $x,y>0$, where $x,y\in [a,b]$, are of the form

where $\hat{x}$, $\hat{y}$, $\tilde{x}$ and $\tilde{y}$ are the same as in (19). If ${\mathrm{\Phi }}_i$ ($i=1,2$) are positive, then Theorem 2.6 applied for $f=f_s\in {\mathrm{\Omega }}_2$ and $g=f_q\in {\mathrm{\Omega }}_2$ yields that there exists ${\xi }_i\in [a,b]$ such that

Since the functions ${\xi }_i\mapsto {\xi }_i^{s-q}$ ($i=1,2$) are invertible for $s\ne q$, we then have

which, together with the fact that ${\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_2)$ ($i=1,2$) are continuous, symmetric and monotonous (by (16)), shows that ${\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_2)$ ($i=1,2$) are means.

Now, by the substitutions $x\to x^t$, $y\to y^t$, $s\to \frac{s}{t}$, $q\to \frac{q}{t}$ ($t\ne 0$, $s\ne q$), where $x,y\in [a,b]$, from (20) we get

We define a new mean (for $i=1,2$) as follows:

These new means are also monotonous. More precisely, for $s,q,u,v\in \mathbb{R}$ such that $s\le u$, $q\le v$, $s\ne q$, $u\ne v$, we have

We know that

equivalently

for $s,q,u,v\in I$ such that $s/t\le u/t$, $q/t\le v/t$ and $t\ne 0$, since ${\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_2)$ ($i=1,2$) are monotonous in both parameters, the claim follows. For $t=0$, we obtain the required result by taking the limit $t\to 0$.

Remark 4.3 If we make the substitutions $x\to a$, $y\to b$, $s\to s-1$ and $t\to t-1$ in our means ${\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_2)$ and ${\mu }_{s,q;t}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_2)$ ($i=1,2$), then the results for the $E_1(r,t)$ means and the generalized $E_1$ means given in [7] are recaptured. In this way our results for means are the generalizations of the above mentioned means.

Example 4.4 Consider the family of functions

defined by

We have $\frac{d^2}{d{x}^2}{h}_s(x)=s^{-x}>0$ which shows that $h_s$ is convex for all $s>0$. Exponential convexity of $s\mapsto \frac{d^2}{d{x}^2}{h}_s(x)=s^{-x}$ on $(0,\mathrm{\infty })$ is given by Example 4.3 in [6]. Arguing as in Example 4.1, we have $s\mapsto {\mathrm{\Phi }}_i(x,y;h_s)$ ($i=1,2$) are exponentially convex.

In this case by taking $\mathrm{\Omega }={\mathrm{\Omega }}_3$ in (17), ${\mathrm{\Xi }}_{s,q;3}^i:={\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_3)$ ($i=1,2$) for $x,y>0$, where $x,y\in [a,b]$, are of the form

where $\hat{x}$, $\hat{y}$, $\tilde{x}$ and $\tilde{y}$ are the same as in (19). By using Theorem 2.6, it follows that

satisfy $min\{a,b\}\le M_{s,q}(x,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_3)\le max\{a,b\}$ and so $M_{s,q}(x,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_3)$ ($i=1,2$) are means, where $L(s,q)$ is a logarithmic mean defined by $L(s,q)=\frac{s-q}{logs-logq}$, $s\ne q$, $L(s,s)=s$.

Example 4.5 Consider the family of functions

defined by

Here, $\frac{d^2}{d{x}^2}{k}_s(x)=e^{-x\sqrt{s}}>0$ which shows that $k_s$ is convex for all $s>0$. Exponential convexity of $s\mapsto \frac{d^2}{d{x}^2}{k}_s(x)=e^{-x\sqrt{s}}$ on $(0,\mathrm{\infty })$ is given by Example 4.4 in [6]. Arguing as in Example 4.1, we have $s\mapsto {\mathrm{\Phi }}_i(x,y;k_s)$ ($i=1,2$) are exponentially convex.

In this case by taking $\mathrm{\Omega }={\mathrm{\Omega }}_4$ in (17), ${\mathrm{\Xi }}_{s,q;4}^i:={\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_4)$ ($i=1,2$) for $x,y>0$, where $x,y\in [a,b]$, are of the form

where $\hat{x}$, $\hat{y}$, $\tilde{x}$ and $\tilde{y}$ are the same as in (19). By using Theorem 2.6, it is easy to see that

satisfy $min\{a,b\}\le M_{s,q}(x,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_4)\le max\{a,b\}$, showing that $M_{s,q}(x,{\mathrm{\Phi }}_i,{\mathrm{\Omega }}_4)$ ($i=1,2$) are means.

Remark 4.6 From (16), it is clear that ${\mu }_{s,q}(x,y,{\mathrm{\Phi }}_i,\mathrm{\Omega })$ ($i=1,2$) for $\mathrm{\Omega }={\mathrm{\Omega }}_1,{\mathrm{\Omega }}_2,{\mathrm{\Omega }}_3\text{ and }{\mathrm{\Omega }}_4$ are monotonous functions in parameters s and q.

The second author’s research was supported by the Croatian Ministry of Science, Education and Sports, under the Research Grant 117-1170889-0888.

Authors and Affiliations

1. Abdus Salam School of Mathematical Sciences, GC University, 68-B, New Muslim Town, Lahore, 54600, Pakistan

   Sadia Khalid & Josip Pečarić

2. Faculty of Textile Technology, University of Zagreb, Prilaz Baruna Filipovića 28A, 10000, Zegreb, Croatia

   Josip Pečarić

Corresponding author

Correspondence to Sadia Khalid.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

Both authors worked jointly on the results and they read and approved the final manuscript.

Open Access This article is distributed under the terms of the Creative Commons Attribution 2.0 International License (https://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

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