NOTE ON HADWIGER FINSLER S INEQUALITIES. 1. Introduction

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Journal of Mathematical Inequalities Volume 6, Number 1 (01), 57 64 NOTE ON HADWIGER FINSLER S INEQUALITIES D.Ş. MARINESCU, M.MONEA, M.OPINCARIU AND M. STROE (Communicated by S. Segura Gomis) Abstract. In this article we present a new proof of the Finsler-Hadwiger inequality, we prove some consequences and one Finsler-Hadwiger type inequality. Finally we use the geometric inequalities that we obtain in this paper to present some algebraic applications. 1. Introduction In [6] and [8], Finsler and Hadwiger proved the following inequality: In any triangle ABC, the following inequalities hold: 4S 3 + Q a + b + c 4S 3 + 3Q, (1) where S is the triangle area and Q =(a b) +(b c) +(c a). Equality occurs when triangle ABC is equilateral. This result can be used to prove other known inequalities. We shall present a few such results and a new proof of the inequality (1). Finally we show another Finsler- Hadwiger type inequality and some algebraic applications.. Inequalities derived from Finsler-Hadwiger inequality For next results, we shall consider a triangle with side lengths a,b,c and area S..1. WEITZENBÖCK S INEQUALITY (1919). [11] In any triangle we have inequality a + b + c 4S 3. Proof. We have a + b + c 4S 3 + Q 4S 3... GORDON S INEQUALITY(1966). [7] In any triangle we have inequality ab + bc + ca 4S 3. Proof. a + b + c 4S 3 + Q is equivalent to ab + bc + ca 4S 3 + a + b + c ab bc ca. Using algebraic inequality a + b + c ab bc ca 0, we conclude that ab + bc + ca 4S 3. Mathematics subject classification (010): 6D05. Keywords and phrases: Finsler-Hadwiger s inequality, Weitzenböck s inequality, means inequality. c D l,zagreb Paper JMI-06-05 57

58 D.Ş. MARINESCU,M.MONEA, M.OPINCARIU AND M. STROE.3. TSINTSIFAS S INEQUALITY(1986). [10] Let m,n, p be real numbers with m + n, n + p and p + m strictly positive. In any triangle we have m n + p a + n m + p b + p m + n c S 3. Proof. Inequality in the statement is equivalent with ( a ) (m + n + p) n + p + b m + p + c S 3 + a + b + c. () m + n But a n + p + b m + p + c (a + b + c) m + n (m + n + p) from Cauchy inequality. Also is equivalent with Then a + b + c Q 4S 3 a + b + c + ab + bc + ac 4S 3 + a + b + c. ( a (m + n + p) n + p + b m + p + ) c (m + n + p) m + n (a + b + c) (m + n + p) (a + b + c) = S 3 + a + b + c, which conclude ()..4. CURRY S INEQUALITY(1966). [3] In any triangle, we have 9abc a + b + c 4S 3. Proof. For the first, we prove algebraic inequality for all x,y,z > 0 This is equivalent with 9xyz (x + y + z) ( xy + yz + zx x y z ) (3) 9xyz x y + x z + xy + y z + xz + yz + 6xyz x 3 y 3 z 3 x 3 + y 3 + z 3 + 3xyz x y + x z + xy + y z + xz + yz ( x 3 x y x z + xyz ) + ( y 3 y x y z + xyz ) + ( z 3 z y z x + xyz ) 0 x(x y)(x z)+y(y x)(y z)+z(z x)(z y) 0

NOTE ON HADWIGER-FINSLER S INEQUALITIES 59 which is true from Schur inequality. Now, (3) is equivalent with 9xyz x + y + z xy + yz + zx x y z 9xyz x + y + z x + y + z (x y) (y z) (z x). This result and Finsler-Hadwiger inequality solve the problem..5. HADWIGER S INEQUALITY(1939). [8] In any triangle the following inequalities hold 1S 3 + Q (a + b + c) 1S 3 + 8Q. Proof. It is an equivalent form of (1). 3. Proof of Finsler-Hadwiger s inequalities Proof. If a,b,c are the side lengths of triangle ABC, then there exist three real numbers x,y,z > 0sothata = y + z, b = x + z and c = x + y. With this notations, we have S = xyz(x + y + z). Inequality (1) is equivalent with a + b + c 3Q 4S 3 a + b + c Q. Then a + b + c 3Q 4S 3 (y + z) +(x + z) +(x + y) 3(x y) 3(y z) 3(z x) 4 3xyz(x + y + z) But from (3) and because is equivalent with xy + yz + zx x y z 3xyz(x + y + z). (4) xy + yz + zx x y z 9xyz x + y + z 3xyz(x + y + z) 7xyz (x + y + z) 3 9xyz x + y + z 3 xyz x + y + z 3 which is Arithmetic and Geometric mean inequality. Thus, (4) is valid. Next 4S 3 a + b + c Q

60 D.Ş. MARINESCU,M.MONEA, M.OPINCARIU AND M. STROE 4 3xyz(x + y + z) (y + z) +(x + z) +(x + y) (x y) (y z) (z x) 3xyz(x + y + z) xy + yz + zx 3xyz(x + y + z) (xy + yz + zx) (xy)(xz)+(xy)(yz)+(xz)(yz) (xy) +(xz) +(zy) which is true. Now, the proof is complete. THEOREM 3.1. Let u, v R. If the inequalities 4S 3 + uq a + b + c 4S 3 + vq (5) are true for any triangle, then u 1 and v 3. Proof. Let triangle ABC with a = b = 1andc = t (0,).Then 4S 3 + uq a + b + c t 3(4 t )+u(1 t) + t. With condition t 0 we obtain u, so u 1. From a + b + c 4S 3 + vq, we obtain + t t 3(4 t )+v(1 t). Condition t goes to 6 v,so3 v. Given the Finsler-Hadwiger inequality, we deduce that the maximum value of number u from (5) is 1 and the minimum value of v is 3 and these constants are best possible. 4. A Finsler-Hadwiger type inequality Let the triangle ABC and set M =( a b + b c + c a ). Then: THEOREM 4.1. In any triangle, we have: 4S 3 + 1 M a + b + c 4S 3 + 3 M. (6) Proof. In this proof we consider a b c. In these conditions we have M = 4(a c). For inequality 4S 3 + 1 M a + b + c,letx,y,z > 0 with a = y + z, b = x + z and c = x + y. Then inequality is equivalent with 4 3xyz(x + y + z)+(x z) x + y + z + xy + xz + yz 3xyz(x + y + z) y + xy + yz + 3xz

NOTE ON HADWIGER-FINSLER S INEQUALITIES 61 3xz y(x + y + z) y(x + y + z)+3xz, which is true because it is the Arithmetic and Geometric mean inequality. For a + b + c 4S 3 + 3 M we prove the first inequality (a b) +(b c) +(c a) 1 M. (7) This is equivalent with a + b + c ab bc ca (a c) b ab bc + ac 0 (b a)(b c) 0, which is true because a b c. Then a + b + c 4S [ 3 + 3 (a b) +(b c) +(c a) ] 4S 3 + 3 M which concludes the proof. THEOREM 4.. Let u, v R. If the inequalities 4S 3 + um a + b + c 4S 3 + vm (8) hold for any triangle then u 1 and v 3. Proof. Let the triangle ABC with a = b = 1andc = t (0,). Then 4S 3 + um a + b + c t 3(4 t )+4u(1 t) + t. With t 0, we obtain 4u, so u 1. Next a + b + c 4S 3 + vm + t t 3(4 t )+4v(1 t). Condition t goes to 6 4v and v 3. Given the inequality (6), we deduce that the maximum value of number u from (8) is 1 and the minimum value of v is 3, so this constants are best possible. REMARK 1. Given the Finsler-Hadwiger s inequality, inequalities of proposition 4.1 and relation (7), we obtain following sequence of inequalities valid for any triangle, 4S 3 + Q 4S 3 + 1 M a + b + c 4S 3 + 3Q 4S 3 + 3 M, where Q =(a b) +(b c) +(c a) and M =( a b + b c + c a ). REMARK. We have equality in (1) if and only if triangle is equilateral. But the inequalities from.1,.,.4 and.5 are consequences of the Finsler-Hadwiger s inequality and equality holds in same conditions. Supplementary, the equality from.3 holds with the conditions m = n = p. In same mode, the inequality from Theorem 4.1 is equality if and only if the triangle is equilateral.

6 D.Ş. MARINESCU,M.MONEA, M.OPINCARIU AND M. STROE 5. Applications Applications that we present below are algebraic inequalities. With the results included in the next lemmas, we can use some geometric arguments to prove these inequalities. These arguments are based on the existence of a triangle with given side lengths and on the inequalities for a triangle. LEMMA 5.1. For all real numbers x, y, z > 0, the following inequality holds x + y < x + z+ y + z. Proof. x + y < x + z+ y + z x + y < x + z + (x + z)(y + z)+y + z 0 < z + (x + z)(y + z) which is true. LEMMA 5.. For all real numbers x,y,z > 0, there exists a triangle with side lengths x + y, x + z, y + z whose area is S = 1 xy + xz + yz. Proof. Lemma 5.1 ensures the existence of a triangle. Its area is S = 1 x + y x + zsinα where α is the angle of the sides of length x + y and x + z. Then cosα = x + y + x + z y z (x + y)(x + z) = x (x + y)(x + z) and xy + xz + yz sin α = 1 cos α =. (x + y)(x + z) Now, we obtain S = 1 xy + xz + yz. APPLICATIONS 1. For all real numbers x,y,z > 0, the following inequality holds (x + y)(x + z) x + y + z + 3(xy + xz + yz). Proof. We use 5. and inequality (1) for the triangle with side lengths x + y, x + z and y + z. We obtain ( ) x + y ( ) 1 x + y x + z 4 3 xy + xz + yz and (x + y)(x + z) (x + y + z) 3(xy + xz + yz) and this concludes the proof.

NOTE ON HADWIGER-FINSLER S INEQUALITIES 63 APPLICATIONS. For all real numbers x,y,z > 0, the following inequality holds 3 (x + y)(x + z) 5x + 5y + 5z + 3(xy + xz + yz). Proof. We use Lemma 5. and other part of inequality (1) for the triangle with side lengths x + y, x + z and y + z. We obtain ( ) x + y 3 ( ) 1 x + y x + z 4 3 xy + xz + yz which is equivalent with 6 (x + y)(x + z) 10(x + y + z) 3(xy + xz + yz) and this concludes the proof. APPLICATIONS 3. (T. Andreescu, G. Dospinescu) [1] For all real numbers a,b,c > 0 and x,y,z > 0, the following inequality holds a (x + y)+ b b + c (x + z)+ c a + c a + b (y + z) 3(xy + xz + yz). Proof. We apply Lemma 5. and inequality from.3 for triangle with side lengths x + y, x + z and y + z. APPLICATIONS 4. For all real numbers a,b,c > 0, the following inequality holds ab a + c b + c + bcb + a c + a + ac b + c a + b 3abc(a + b + c). Proof. The inequality is equivalent with a (ab + bc)+ b (ac + bc)+ c b + c a + c a + b (ab + ac) 3(ab ac + ab bc + ac bc). This is true by using the Lemma 5. for the real numbers ab,ac and bc and the inequality from.3. APPLICATIONS 5. For all real numbers x,y,z > 0 satisfying x + y + z = 1, the following inequality holds 1 x + 1 y + 1 z 3 xyz. Proof. We have 1 x, 1 y, 1 z > 0, so numbers 1x + 1 y, 1 x + 1 z and 1y + 1 z the side lengths of a triangle. The area of this triangle is 1 1 xy + 1 xz + 1 yz = 1 z + y + z = 1 xyz xyz. could be

64 D.Ş. MARINESCU,M.MONEA, M.OPINCARIU AND M. STROE Apply inequality from (.1) and obtain and this concludes the proof. 1 x + 1 y + 1 x + 1 z + 1 y + 1 z 3 xyz REFERENCES [1] T. ANDREESCU,G.DOSPINESCU,M.LASCU,M.TETIVA, Old and New Inequalities, GIL Publishing House, Zalau 004. [] O. BOTTEMA, R.Z. DJORDJEVIĆ, R.R. JANIĆ, D.S. MITRINOVIĆ, P.M. VASIĆ, Geometric Inequalities, Wolters-Noordhoe Publishing, Groningen 1969. [3] T.R. CURRY, The American Mathematical Monthly, 73 (1966), no., problem E 1861. [4] P.H. DUC, An Unexpectedly Useful Inequality, Mathematical Reflections, 008, Issue 1. [5] A. ENGEL, Problem-Solving Strategies, Springer Verlag, New York, 1998. [6] P. VON FINSLER, H. HADWIGER, Einige Relationen im Dreieck, Commentarii Mathematici Helvetici, 10 (1937), no. 1, 316 36. [7] V.O. GORDON, Matematika v Skole, 1966, No. 1, 89. [8] H. HADWIGER, Jber. Deutsch. Math. Verein., 49 (1939), 35 39. [9] D.S. MITRINOVIĆ, J.E. PEČARIĆ, V. VOLENEC, Recent Advances in Geometric Inequalities, Kluwer Academic Publisher, 1989. [10] G. TSINTSIFAS, The American Mathematical Monthly, 93 (1986), no. 5, problem E 3150. [11] R. WEITZENBÖCK, Uber eine Ungleichung in der Dreiecksgeometrie, Mathematische Zeitschrift, 5 (1919), no. 1, 137 146. (Received October 30, 009) D.Ş. Marinescu Colegiul Naţional Iancu de Hunedoara Hunedoara, Romania e-mail: marinescuds@gmail.com M. Monea Colegiul Naţional Decebal Deva, Romania e-mail: mihaimonea@yahoo.com M. Opincariu Colegiul Naţional Avram Iancu Brad, Romania e-mail: opincariumihai@yahoo.com M. Stroe Colegiul Economic Emanoil Gojdu Hunedoara, Romania e-mail: maricu stroe@yahoo.com Journal of Mathematical Inequalities www.ele-math.com jmi@ele-math.com

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