On the Hermite-Hadamard Inequality and Other Integral Inequalities Involving Two Functions

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Set, E, Ozdemir, M and Dragomir, Sever S (2010) On the Hermite-Hadamard Inequality and Other Integral Inequalities Involving Two Functions. Journal of Inequalities and Applications, 2010. pp. 1-9. ISSN 1025-5834

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Volume 2010, Article ID 148102,9pages doi:10.1155/2010/148102

Research Article

On the Hermite-Hadamard Inequality and Other Integral Inequalities Involving Two Functions

Erhan Set,

¹

M. Emin ¨ Ozdemir,

²

and Sever S. Dragomir

³

1Department of Mathematics, K. K. Education Faculty, Atat ¨urk University, 25240 Erzurum, Turkey

2Graduate School of Natural and Applied Sciences, A˘grı˙Ibrahim C¸ec¸en University, A˘grı04100, Turkey

3Research Group in Mathematical Inequalities & Applications, School of Engineering & Science, Victoria University, P.O. Box 14428, Melbourne 8001, Australia

Correspondence should be addressed to Erhan Set,erhanset@yahoo.com Received 25 September 2009; Revised 25 March 2010; Accepted 31 March 2010 Academic Editor: Paolo E. Ricci

Copyrightq2010 Erhan Set et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

We establish some new Hermite-Hadamard-type inequalities involving product of two functions.

Other integral inequalities for two functions are obtained as well. The analysis used in the proofs is fairly elementary and based on the use of the Minkowski, H ¨older, and Young inequalities.

1. Introduction

Integral inequalities have played an important role in the development of all branches of Mathematics.

In1,2, Pachpatte established some Hermite-Hadamard-type inequalities involving two convex and log-convex functions, respectively. In3, Bakula et al. improved Hermite- Hadamard type inequalities for products of two m-convex and α, m-convex functions.

In 4, analogous results for s-convex functions were proved by Kirmaci et al.. General companion inequalities related to Jensen’s inequality for the classes ofm-convex andα, m- convex functions were presented by Bakula et al.see5.

For several recent results concerning these types of inequalities, see 6–12 where further references are listed.

The aim of this paper is to establish several new integral inequalities for nonnegative and integrable functions that are related to the Hermite-Hadamard result. Other integral inequalities for two functions are also established.

2 Journal of Inequalities and Applications In order to prove some inequalities related to the products of two functions we need the following inequalities. One of inequalities of this type is the following one.

Barnes-Gudunova-Levin Inequality (see [13–15] and references therein)

Letf,gbe nonnegative concave functions ona, b. Then, forp, q >1 we have _b

a

fx^pdx

_1/pb

a

gx^qdx _1/q

≤B p, q

b a

fxgxdx, 1.1

where

B p, q

6b−a^1/p1/q−1

p1_1/p

q1_1/q. 1.2

In the special caseqpwe have _b

a

fx^pdx

_1/pb

a

gx^pdx _1/p

≤B p, p

b a

fxgxdx 1.3

with

B p, p

6b−a^2/p−1

p1_2/p . 1.4

To prove our main results we recall some concepts and definitions.

Letx x1, x2, . . . , xn andp p1, p2, . . . , pnbe two positiven-tuples, and letr ∈ R∪ {∞,−∞}. Then, on putting P_{n n}

k1p_k,therth power mean ofxwith weightspis defined16by

M^r_n

⎧⎪

⎪⎪

⎪⎪

⎪⎪

⎪⎪

⎪⎪

⎪⎪

⎨

⎪⎪

⎪⎪

⎪⎪

⎪⎪

⎪⎪

⎪⎪

⎪⎩ 1

P_n n k1

pkx^r_{k 1/r}

, r / ∞,0,−∞, _n

k1

x^p_k^k _1/Pn

, r 0,

minx1, x2, . . . , xn, r −∞, maxx1, x2, . . . , xn, r∞.

1.5

Note that if−∞ ≤r < s≤ ∞, then

M^r_n ≤M_n^s 1.6

see, e.g.,10, page 15.

Letf:a, b → Randp≥1. Thep-norm of the functionfona, bis defined by

f

p

⎧⎪

⎪⎨

⎪⎪

⎩ _b

a

fx^pdx 1/p

, 1≤p <∞,

supfx, p∞,

1.7

andL^pa, bis the set of all functionsf :a, b → Rsuch thatf_p<∞.

One can rewrite the inequality1.1as follows:

f

pg

q ≤B p, q

b a

fxgxdx. 1.8

For several recent results concerningp-norms we refer the interested reader to17.

Also, we need some important inequalities.

Minkowski Integral Inequality (see page 1 in [18])

Letp≥1, 0<_b

afx^pdx <∞, and 0<_b

agx^pdx <∞. Then _b

a

fx gxp

dx _1/p

≤ _b

a

fx^pdx _1/p

_b

a

gx^pdx _1/p

. 1.9

Hermite-Hadamard’s Inequality (see page 10 in [10])

Letf:I ⊂R → Rbe a convex function on intervalIof real numbers anda, b∈Iwitha < b.

Then the following Hermite-Hadamard inequality for convex functions holds:

f ab

2

≤ 1 b−a

_b

a

fxdx≤ fa fb

2 . 1.10

If the functionfis concave, the inequality1.10can be written as follows:

fa fb

2 ≤ 1

b−a _b

a

fxdx≤f ab

2

. 1.11

For recent results, refinements, counterparts, generalizations, and new Hermite-Hadamard- type inequalities, see19–21.

4 Journal of Inequalities and Applications

A Reversed Minkowski Integral Inequality (see page 2 in [18])

Letfandgbe positive functions satisfying

0< m≤ fx

gx ≤M, x∈a, b. 1.12 Then, puttingc Mm1 M1/m1M1, we have

_b

a

fx^pdx 1/p

_b

a

gx^pdx ^1/p

≤c _b

a

fx gxp

dx 1/p

. 1.13

One of the most important inequalities of analysis is H ¨older’s integral inequality which is stated as followsfor its variant see10, page 106.

H¨older Integral Inequality

Letp >1 and 1/p1/q1.Iffandgare real functions defined ona, band if|f|^pand|g|^q are integrable functions ona, b, then

_b

a

fxgxdx≤ _b

a

fx^pdx

_1/pb

a

gx^qdx _1/q

, 1.14

with equality holding if and only ifA|fx|^p B|gx|^qalmost everywhere, whereAandB are constants.

Remark 1.1. Observe that whenever,f^pis concave ona, b,the nonnegative functionfis also concave ona, b. Namely,

fta 1−tbp≥tfa^p 1−tfb^p, 1.15

that is,

fta 1−tb≥

tfa^p 1−tfb^p_1/p 1.16

andp >1; using the power-mean inequality1.6, we obtain

fta 1−tb≥tfa 1−tfb. 1.17

Forq >1, similarly ifg^qis concave ona, b,the nonnegative functiongis concave on a, b.

2. The Results

Theorem 2.1. Letp, q >1and letf, g :a, b → R,a < b, be nonnegative functions such thatf^p andg^qare concave ona, b. Then

fa fb

2 ×ga gb

2 ≤ 1

b−a^1/p1/qB p, q

b a

fxgxdx, 2.1

and if1/p1/q1, then one has

1 b−a

_b

a

fxgxdx≤f ab

2

g ab

2

. 2.2

HereB·,·is the Barnes-Gudunova-Levin constant given by1.1.

Proof. Sincef^p, g^qare concave functions ona, b, then from1.11andRemark 1.1we get fa^pfb^p

2

1/p

≤ 1

b−a^1/p _b

a

fx^pdx _1/p

≤f ab

2

, ga^qgb^q

2

1/q

≤ 1

b−a^1/q _b

a

gx^qdx _1/q

≤g ab

2

.

2.3

By multiplying the above inequalities, we obtain2.4and2.5 fa^pfb^p

2

1/pga^qgb^q 2

1/q

≤ 1

b−a^1/p1/q _b

a

fx^pdx 1/p

× _b

a

gx^qdx 1/q

,

2.4

1 b−a^1/p1/q

_b

a

fx^pdx

_1/pb

a

gx^qdx _1/q

≤f ab

2

g ab

2

. 2.5

Ifp, q >1, then it easy to show that

fa^pfb^p 2

1/p

≥ fa fb

2 ,

ga^qgb^q 2

1/q

≥ ga gb

2 .

2.6

Thus, by applying Barnes-Gudunova-Levin inequality to the right-hand side of2.4with 2.6, we get2.1.

6 Journal of Inequalities and Applications Applying the H ¨older inequality to the left-hand side of2.5with 1/p1/q 1, we get2.2.

Theorem 2.2. Letp≥1, 0<_b

afx^pdx <∞, and0<_b

agx^pdx <∞, and letf, g:a, b → R be positive functions with

0< m≤ f

g ≤M, ∀x∈a, b, a < b. 2.7 Then

f²

pg² f p

pg

p

≥ 1

s−2, 2.8

wheresM/M1m1.

Proof. Sincef, gare positive, as in the proof of the inequality1.13 see18, page 2, we have that

_b

a

fx^pdx 1/p

≤ M M1

_b

a

fx gxp

dx 1/p

, _b

a

gx^pdx _1/p

≤ 1 m1

_b

a

fx gx_p dx

_1/p .

2.9

By multiplying the above inequalities, we get _b

a

fx^pdx

_1/pb

a

gx^pdx _1/p

≤s _b

a

fx gx_p dx

_2/p

. 2.10

Since_b

afx^pdx^1/p f_pand_b

agx^pdx^1/pg_p,by applying the Minkowski integral inequality to the right hand side of2.10, we obtain inequality2.8.

Theorem 2.3. Letf^pandg^qbe as inTheorem 2.1. Then the following inequality holds:

fa fb_p

ga gb_q

2^pq ≤ 1

b−a²f^p

pg^q

q. 2.11

Proof. Iff^p,g^qare concave ona, b, then from1.11we get fa^pfb^p

2 ≤ 1

b−a _b

a

fx^pdx, ga^qgb^q

2 ≤ 1

b−a _b

a

gx^qdx,

2.12

which imply that fa^pfb^p

ga^qgb^q

4 ≤ 1

b−a² _b

a

fx^pdx _b

a

gx^qdx

. 2.13

On the other hand, ifp, q≥1,from1.6we get fa^pfb^p

2

1/p

≥2⁻¹

fa fb ,

ga^qgb^q 2

1/q

≥2⁻¹

ga gb

, 2.14

or

fa^pfb^p 2 ≥2^−p

fa fbp

, ga^qgb^q 2 ≥2^−q

ga gbq

, 2.15

which imply that

fa^pfb^p

ga^qgb^q

4 ≥

fa fb_p

ga gb_q 2^−pq.

2.16

Combining2.13and2.16, we obtain the desired inequality as fa fb_p

ga gb_q

2^−pq≤ 1

b−a²f^p

pg^q

q, 2.17

that is,

fa fb_p

ga gb_q

≤ 2^pq b−a²f^p

pg^q

q. 2.18

To prove the following theorem we need the following Young-type inequalitysee7, page 117:

xy≤ 1 px^p1

qy^q, for any x, y≥0, p >1, 1 p 1

q 1. 2.19

Theorem 2.4. Letf, g:a, b → Rbe functions such thatf^p, g^p, andfgare inL₁a, b, and

0< m≤ fx

gx ≤M, ∀x∈a, b, a, b∈0,∞. 2.20

8 Journal of Inequalities and Applications Then

_b

a

fxgxdx≤c1

⎛

⎝f^p

pg^p

p

2

⎞

⎠c2

⎛

⎝f^q

qg^q

q

2

⎞

⎠, 2.21

where

c1 2^p p

M M1

p

, c2 2^q q

1 m1

q

2.22

and1/p1/q1 withp >1.

Proof. From 0< m≤fx/gx≤M, for allx∈a, b,we have

fx≤ M

M1

fx gx , gx≤ 1

m1

fx gx .

2.23

From2.19with2.23we obtain _b

a

fxgxdx≤ 1 p

_b

a

fx^pdx 1 q

_b

a

gx^qdx

≤ 1 p

M M1

p_b

a

fx gx_p dx 1

q 1

m1 q_b

a

fx gx_q dx.

2.24 Using the elementary inequalitycd^p ≤2^p−1c^pd^p,p >1 andc, d ∈Rin2.24, we get

_b

a

fxgxdx≤ 1 p

M M1

p

2^p−1 _b

a

fx^pgx^p dx 1

q 1

m1 _q

2^q−1 _b

a

fx^qgx^q dx

2^p p

M M1

_p⎛

⎝f^p

pg^p

p

2

⎞

⎠ 2^q q

1 m1

_q⎛

⎝f^q

qg^q

q

2

⎞

⎠.

2.25

This completes the proof of the inequality in2.21.

Acknowledgment

The authors thank the careful referees for some good advices which have improved the final version of this paper.

References

1 B. G. Pachpatte, “On some inequalities for convex functions,”RGMIA Research Report Collection E, vol.

6, 2003.

2 B. G. Pachpatte, “A note on integral inequalities involving two log-convex functions,”Mathematical Inequalities & Applications, vol. 7, no. 4, pp. 511–515, 2004.

3 M. K. Bakula, M. E. ¨Ozdemir, and J. Peˇcari´c, “Hadamard type inequalities form-convex andα, m- convex functions,”Journal of Inequalities in Pure and Applied Mathematics, vol. 9, no. 4, article 96, 2008.

4 U. S. Kirmaci, M. K. Bakula, M. E. ¨Ozdemir, and J. Peˇcari´c, “Hadamard-type inequalities fors-convex functions,”Applied Mathematics and Computation, vol. 193, no. 1, pp. 26–35, 2007.

5 M. K. Bakula, J. Peˇcari´c, and M. Ribiˇci´c, “Companion inequalities to Jensen’s inequality form-convex andα, m-convex functions,”Journal of Inequalities in Pure and Applied Mathematics, vol. 7, no. 5, article 194, 2006.

6 M. K. Bakula and J. Peˇcari´c, “Note on some Hadamard-type inequalities,”Journal of Inequalities in Pure and Applied Mathematics, vol. 5, no. 3, article 74, 2004.

7 S. S. Dragomir, R. P. Agarwal, and N. S. Barnett, “Inequalities for beta and gamma functions via some classical and new integral inequalities,”Journal of Inequalities and Applications, vol. 5, no. 2, pp. 103–

165, 2000.

8 G. H. Hardy, J. E. Littlewood, and G. P ´olya,Inequalities, Cambridge Mathematical Library, Cambridge , UK, 1998.

9 U. S. Kirmaci and M. E. ¨Ozdemir, “Some inequalities for mappings whose derivatives are bounded and applications to special means of real numbers,”Applied Mathematics Letters, vol. 17, no. 6, pp.

641–645, 2004.

10 D. S. Mitrinovi´c, J. E. Peˇcari´c, and A. M. Fink, Classical and New Inequalities in Analysis, vol. 61 of Mathematics and Its Applications (East European Series), Kluwer Academic Publishers, Dordrecht, The Netherlands, 1993.

11 M. E. ¨Ozdemir and U. S. Kırmacı, “Two new theorem on mappings uniformly continuous and convex with applications to quadrature rules and means,”Applied Mathematics and Computation, vol. 143, no.

2-3, pp. 269–274, 2003.

12 B. G. Pachpatte,Inequalities for Differentiable and Integral Equations, Academic Press, Boston, Mass, USA, 1997.

13 J. Peˇcari´c and T. Pejkovi´c, “On an integral inequality,” Journal of Inequalities in Pure and Applied Mathematics, vol. 5, no. 2, article 47, 2004.

14 J. E. Peˇcari´c, F. Proschan, and Y. L. Tong,Convex Functions, Partial Orderings, and Statistical Applications, vol. 187 ofMathematics in Science and Engineering, Academic Press, Boston, Mass, USA, 1992.

15 T. K. Pog´any, “On an open problem of F. Qi,”Journal of Inequalities in Pure and Applied Mathematics, vol. 3, no. 4, article 54, 2002.

16 P. S. Bullen, D. S. Mitrinovi´c, and P. M. Vasi´c,Means and Their Inequalities, vol. 31 ofMathematics and Its Applications (East European Series), D. Reidel, Dordrecht, The Netherlands, 1988.

17 U. S. Kirmaci, M. Klariˇci´c, M. E. ¨Ozdemir, and J. Peˇcari´c, “On some inequalities forp-norms,”Journal of Inequalities in Pure and Applied Mathematics, vol. 9, no. 1, article 27, 2008.

18 L. Bougoffa, “On Minkowski and Hardy integral inequalities,”Journal of Inequalities in Pure and Applied Mathematics, vol. 7, no. 2, article 60, 2006.

19 M. Alomari and M. Darus, “On the Hadamard’s inequality for log-convex functions on the coordinates,”Journal of Inequalities and Applications, vol. 2009, Article ID 283147, 13 pages, 2009.

20 C. Dinu, “Hermite-Hadamard inequality on time scales,”Journal of Inequalities and Applications, vol.

2008, Article ID 287947, 24 pages, 2008.

21 S. S. Dragomir and C. E. M. Pearce,Selected Topics on Hermite-Hadamard Inequalities and Applications, RGMIA Monographs, Victoria University, Melbourne, Australia, 2000.