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In mathematics, Schur's inequality, named after Issai Schur, establishes that for all non-negative real numbers x, y, z and a positive number t,

x^{t}(x-y)(x-z)+y^{t}(y-z)(y-x)+z^{t}(z-x)(z-y)\geq 0

with equality if and only if x = y = z or two of them are equal and the other is zero. When t is an even positive integer, the inequality holds for all real numbers x, y and z.

When $t=1$ , the following well-known special case can be derived:

x^{3}+y^{3}+z^{3}+3xyz\geq xy(x+y)+xz(x+z)+yz(y+z)

Proof

Since the inequality is symmetric in $x,y,z$ we may assume without loss of generality that $x\geq y\geq z$ . Then the inequality

(x-y)[x^{t}(x-z)-y^{t}(y-z)]+z^{t}(x-z)(y-z)\geq 0\,

clearly holds, since every term on the left-hand side of the equation is non-negative. This rearranges to Schur's inequality.

Extension

A generalization of Schur's inequality is the following: Suppose a,b,c are positive real numbers. If the triples (a,b,c) and (x,y,z) are similarly sorted, then the following inequality holds:

a(x-y)(x-z)+b(y-z)(y-x)+c(z-x)(z-y)\geq 0.

In 2007, Romanian mathematician Valentin Vornicu showed that a yet further generalized form of Schur's inequality holds:

Consider $a,b,c,x,y,z\in \mathbb {R}$ , where $a\geq b\geq c$ , and either $x\geq y\geq z$ or $z\geq y\geq x$ . Let $k\in \mathbb {Z} ^{+}$ , and let $f:\mathbb {R} \rightarrow \mathbb {R} _{0}^{+}$ be either convex or monotonic. Then,

{f(x)(a-b)^{k}(a-c)^{k}+f(y)(b-a)^{k}(b-c)^{k}+f(z)(c-a)^{k}(c-b)^{k}\geq 0}.\,

The standard form of Schur's is the case of this inequality where x = a, y = b, z = c, k = 1, ƒ(m) = m^r.^[1]

Notes

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↑ Vornicu, Valentin; Olimpiada de Matematica... de la provocare la experienta; GIL Publishing House; Zalau, Romania.

[1] Vornicu, Valentin; Olimpiada de Matematica... de la provocare la experienta; GIL Publishing House; Zalau, Romania.

[1]

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+In [[mathematics]], '''Schur's [[inequality (mathematics)|inequality]]''', named after [[Issai Schur]],
+establishes that for all [[Nonnegative number|non-negative]] [[real number]]s
+''x'', ''y'', ''z'' and a [[positive number]] ''t'',
+:<math>x^t (x-y)(x-z) + y^t (y-z)(y-x) + z^t (z-x)(z-y) \ge 0</math>
+with equality if and only if ''x = y = z'' or two of them are equal and the other is zero. When ''t'' is an even positive [[integer]], the inequality holds for all real numbers ''x'', ''y'' and ''z''.
+When <math>t=1</math>, the following well-known special case can be derived:
+:<math>x^3 + y^3 + z^3 + 3xyz \geq xy(x+y) + xz(x+z) + yz(y+z)</math>
+== Proof ==
+Since the inequality is symmetric in <math>x,y,z</math> we may assume without loss of generality that <math> x \geq y \geq z</math>. Then the inequality
+: <math>(x-y)[x^t(x-z)-y^t(y-z)]+z^t(x-z)(y-z) \geq 0\,</math>
+clearly holds, since every term on the left-hand side of the equation is non-negative. This rearranges to Schur's inequality.
+== Extension ==
+A [[generalization]] of Schur's inequality is the following:
+Suppose ''a,b,c'' are positive real numbers. If the triples ''(a,b,c)'' and ''(x,y,z)'' are [[Order isomorphic|similarly sorted]], then the following inequality holds:
+:<math>a (x-y)(x-z) + b (y-z)(y-x) + c (z-x)(z-y) \ge 0.</math>
+In 2007, [[Romania]]n mathematician [[Valentin Vornicu]] showed that a yet further generalized form of Schur's inequality holds:
+Consider <math>a,b,c,x,y,z \in \mathbb{R}</math>, where <math>a \geq b \geq c</math>, and either <math>x \geq y \geq z</math> or <math>z \geq y \geq x</math>. Let <math>k \in \mathbb{Z}^{+}</math>, and let <math>f:\mathbb{R} \rightarrow \mathbb{R}_{0}^{+}</math> be either [[convex function|convex]] or [[monotonic]]. Then,
+: <math>{f(x)(a-b)^k(a-c)^k+f(y)(b-a)^k(b-c)^k+f(z)(c-a)^k(c-b)^k \geq 0}.\,</math>
+The standard form of Schur's is the case of this inequality where ''x'' = ''a'', ''y'' = ''b'', ''z'' = ''c'', ''k'' = 1, ƒ(''m'') = ''m''<sup>''r''</sup>.<ref>Vornicu, Valentin; ''Olimpiada de Matematica... de la provocare la experienta''; GIL Publishing House; Zalau, Romania.</ref>
+==Notes==
+{{reflist}}
+[[Category:Inequalities]]
+[[Category:Articles containing proofs]]

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Proof

Extension

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