Difference between revisions of "2005 IMO Problems/Problem 3"

Latest revision as of 02:37, 4 September 2025

\documentclass{article} \usepackage{amsmath} \usepackage{amssymb} \begin{document}

\section*{Problem} Let x , y , z x,y,z be positive real numbers such that x y z ≥ 1 xyz≥1. Prove that:

x 5 − x 2 x 5 + y 2 + z 2 + y 5 − y 2 y 5 + z 2 + x 2 + z 5 − z 2 z 5 + x 2 + y 2 ≥ 0. x 5

+y

2

+z

2

x 5

−x

2

y 5

+z

2

+x

2

y 5

−y

2

z 5

+x

2

+y

2

z 5

−z

2

≥0.

\section*{Solution} We first show that for any positive real numbers x , y , z x,y,z, we have

x 5 − x 2 x 5 + y 2 + z 2 ≥ x 4 − x x 4 + y 2 + z 2 . x 5

+y

2

+z

2

x 5

−x

2

≥

x 4

+y

2

+z

2

x 4

−x

Indeed, consider the difference: \begin{align*} &\frac{x^5 - x^2}{x^5 + y^2 + z^2} - \frac{x^4 - x}{x^4 + y^2 + z^2} \ &= \frac{(x^5 - x^2)(x^4 + y^2 + z^2) - (x^4 - x)(x^5 + y^2 + z^2)}{(x^5 + y^2 + z^2)(x^4 + y^2 + z^2)}. \end{align*} The numerator simplifies as follows: \begin{align*} &(x^5 - x^2)(x^4 + y^2 + z^2) - (x^4 - x)(x^5 + y^2 + z^2) \ &= x^5x^4 + x^5(y^2+z^2) - x^2x^4 - x^2(y^2+z^2) - x^4x^5 - x^4(y^2+z^2) + x x^5 + x(y^2+z^2) \ &= x^5(y^2+z^2) - x^2(y^2+z^2) - x^4(y^2+z^2) + x(y^2+z^2) \ &= (y^2+z^2)(x^5 - x^4 - x^2 + x) \ &= (y^2+z^2)x(x^4 - x^3 - x + 1) \quad \text{(but wait, check: actually, } x^5 - x^4 - x^2 + x = x(x^4 - x^3 - x + 1) \text{? That doesn't factor nicely)}. \end{align*} Alternatively, note that:

x 5 − x 2 = x 2 ( x 3 − 1 ) = x 2 ( x − 1 ) ( x 2 + x + 1 ) , x 4 − x = x ( x 3 − 1 ) = x ( x − 1 ) ( x 2 + x + 1 ) . x 5

−x

2

=x

2

(x

3

−1)=x

2

(x−1)(x

2

+x+1),x

4

−x=x(x

3

−1)=x(x−1)(x

2

+x+1).

So then: \begin{align*} &\frac{x^5 - x^2}{x^5 + y^2 + z^2} - \frac{x^4 - x}{x^4 + y^2 + z^2} \ &= \frac{x^2(x-1)(x^2+x+1)}{x^5 + y^2 + z^2} - \frac{x(x-1)(x^2+x+1)}{x^4 + y^2 + z^2} \ &= x(x-1)(x^2+x+1) \left( \frac{x}{x^5 + y^2 + z^2} - \frac{1}{x^4 + y^2 + z^2} \right). \end{align*} Now, combine the terms inside the parentheses:

x x 5 + y 2 + z 2 − 1 x 4 + y 2 + z 2 = x ( x 4 + y 2 + z 2 ) − ( x 5 + y 2 + z 2 ) ( x 5 + y 2 + z 2 ) ( x 4 + y 2 + z 2 ) = ( x 5 + x ( y 2 + z 2 ) ) − ( x 5 + y 2 + z 2 ) ( x 5 + y 2 + z 2 ) ( x 4 + y 2 + z 2 ) = ( x − 1 ) ( y 2 + z 2 ) ( x 5 + y 2 + z 2 ) ( x 4 + y 2 + z 2 ) . x 5

+y

2

+z

2

x

−

x 4

+y

2

+z

2

1

(x 5

+y

2

+z

2

)(x

4

+y

2

+z

2

x(x 4

+y

2

+z

2

)−(x

5

+y

2

+z

2

(x 5

+y

2

+z

2

)(x

4

+y

2

+z

2

(x 5

+x(y

2

+z

2

))−(x

5

+y

2

+z

2

(x 5

+y

2

+z

2

)(x

4

+y

2

+z

2

(x−1)(y 2

+z

2

Thus, the entire difference becomes:

x ( x − 1 ) ( x 2 + x + 1 ) ⋅ ( x − 1 ) ( y 2 + z 2 ) ( x 5 + y 2 + z 2 ) ( x 4 + y 2 + z 2 ) = x ( x − 1 ) 2 ( x 2 + x + 1 ) ( y 2 + z 2 ) ( x 5 + y 2 + z 2 ) ( x 4 + y 2 + z 2 ) ≥ 0. x(x−1)(x 2

+x+1)⋅

(x 5

+y

2

+z

2

)(x

4

+y

2

+z

2

(x−1)(y 2

+z

2

(x 5

+y

2

+z

2

)(x

4

+y

2

+z

2

x(x−1) 2

(x

2

+x+1)(y

2

+z

2

≥0.

Hence,

x 5 − x 2 x 5 + y 2 + z 2 ≥ x 4 − x x 4 + y 2 + z 2 . x 5

+y

2

+z

2

x 5

−x

2

≥

x 4

+y

2

+z

2

x 4

−x

Similarly, we have the analogous inequalities for y y and z z. Therefore, it suffices to prove that

x 4 − x x 4 + y 2 + z 2 + y 4 − y y 4 + z 2 + x 2 + z 4 − z z 4 + x 2 + y 2 ≥ 0 , x 4

+y

2

+z

2

x 4

−x

y 4

+z

2

+x

2

y 4

−y

z 4

+x

2

+y

2

z 4

−z

≥0,

or equivalently,

x 4 x 4 + y 2 + z 2 + y 4 y 4 + z 2 + x 2 + z 4 z 4 + x 2 + y 2 ≥ x x 4 + y 2 + z 2 + y y 4 + z 2 + x 2 + z z 4 + x 2 + y 2 . (1) x 4

+y

2

+z

2

x 4

y 4

+z

2

+x

2

y 4

z 4

+x

2

+y

2

z 4

≥

x 4

+y

2

+z

2

x

y 4

+z

2

+x

2

y

z 4

+x

2

+y

2

z

.(1)

Let t = x + y + z t=x+y+z. Since x , y , z > 0 x,y,z>0 and x y z ≥ 1 xyz≥1, by AM–GM we have t ≥ 3 x y z 3 ≥ 3 t≥3 3

xyz

≥3. Also, note that

x y + y z + z x ≤ t 2 3 xy+yz+zx≤ 3 t 2

and

x 2 + y 2 + z 2 ≥ t 2 3 x 2

+y

2

+z

2

≥

3 t 2

Now, we estimate the right-hand side of (1). By the Cauchy–Schwarz inequality, we have:

( x 2 + y 2 + z 2 ) 2 ≤ ( x 4 + y 2 + z 2 ) ( 1 + y 2 + z 2 ) , (x 2

+y

2

+z

2

≤(x

4

+y

2

+z

2

)(1+y

2

+z

2

),

since

( x 2 + y 2 + z 2 ) 2 = ( x 2 ⋅ 1 + y ⋅ y + z ⋅ z ) 2 ≤ ( x 4 + y 2 + z 2 ) ( 1 2 + y 2 + z 2 ) = ( x 4 + y 2 + z 2 ) ( 1 + y 2 + z 2 ) . (x 2

+y

2

+z

2

=(x

2

⋅1+y⋅y+z⋅z)

2

≤(x

4

+y

2

+z

2

)(1

2

+y

2

+z

2

)=(x

4

+y

2

+z

2

)(1+y

2

+z

2

).

It follows that

1 x 4 + y 2 + z 2 ≤ 1 + y 2 + z 2 ( x 2 + y 2 + z 2 ) 2 , x 4

+y

2

+z

2

1

≤

(x 2

+y

2

+z

2

1+y 2

+z

2

and multiplying by x x (which is positive) gives:

x x 4 + y 2 + z 2 ≤ x ( 1 + y 2 + z 2 ) ( x 2 + y 2 + z 2 ) 2 . x 4

+y

2

+z

2

x

≤

(x 2

+y

2

+z

2

x(1+y 2

+z

2

Similarly,

y y 4 + z 2 + x 2 ≤ y ( 1 + z 2 + x 2 ) ( x 2 + y 2 + z 2 ) 2 , z z 4 + x 2 + y 2 ≤ z ( 1 + x 2 + y 2 ) ( x 2 + y 2 + z 2 ) 2 . y 4

+z

2

+x

2

y

≤

(x 2

+y

2

+z

2

y(1+z 2

+x

2

z 4

+x

2

+y

2

z

≤

(x 2

+y

2

+z

2

z(1+x 2

+y

2

Summing these, we obtain:

∑ x x 4 + y 2 + z 2 ≤ 1 ( x 2 + y 2 + z 2 ) 2 [ ∑ x + ∑ x ( y 2 + z 2 ) ] . ∑ x 4

+y

2

+z

2

x

≤

(x 2

+y

2

+z

2

1

[∑x+∑x(y

2

+z

2

)].

Now, note that

∑ x ( y 2 + z 2 ) = ∑ ( x y 2 + x z 2 ) = ( x y 2 + x z 2 ) + ( y z 2 + y x 2 ) + ( z x 2 + z y 2 ) = ( x + y + z ) ( x y + y z + z x ) − 3 x y z . ∑x(y 2

+z

2

)=∑(xy

2

+xz

2

)=(xy

2

+xz

2

)+(yz

2

+yx

2

)+(zx

2

+zy

2

)=(x+y+z)(xy+yz+zx)−3xyz.

Thus,

∑ x x 4 + y 2 + z 2 ≤ t + t ( x y + y z + z x ) − 3 x y z ( x 2 + y 2 + z 2 ) 2 . ∑ x 4

+y

2

+z

2

x

≤

(x 2

+y

2

+z

2

t+t(xy+yz+zx)−3xyz

Since x y z ≥ 1 xyz≥1, we have − 3 x y z ≤ − 3 −3xyz≤−3. Also, x y + y z + z x ≤ t 2 3 xy+yz+zx≤ 3 t 2

and

x 2 + y 2 + z 2 ≥ t 2 3 x 2

+y

2

+z

2

≥

3 t 2

, so

( x 2 + y 2 + z 2 ) 2 ≥ ( t 2 3 ) 2 = t 4 9 . (x 2

+y

2

+z

2

≥(

3 t 2

2

9 t 4

Therefore,

∑ x x 4 + y 2 + z 2 ≤ t + t ⋅ t 2 3 − 3 ( t 2 / 3 ) 2 = t + t 3 3 − 3 t 4 / 9 = 9 ( t + t 3 3 − 3 ) t 4 = 9 t + 3 t 3 − 27 t 4 = 3 t 3 + 9 t − 27 t 4 . ∑ x 4

+y

2

+z

2

x

≤

(t 2

/3)

2

t+t⋅ 3 t 2

−3

t 4

/9

t+ 3 t 3

−3

t 4

9(t+ 3 t 3

−3)

t 4

9t+3t 3

−27

t 4

3t 3

+9t−27

We now show that

3 t 3 + 9 t − 27 t 4 ≤ 1. t 4

3t 3

+9t−27

≤1.

This is equivalent to

3 t 3 + 9 t − 27 ≤ t 4 ⇔ t 4 − 3 t 3 − 9 t + 27 ≥ 0. 3t 3

+9t−27≤t

4

⇔t

4

−3t

3

−9t+27≥0.

Factor the left-hand side:

t 4 − 3 t 3 − 9 t + 27 = ( t − 3 ) ( t 3 − 9 ) . t 4

−3t

3

−9t+27=(t−3)(t

3

−9).

For t ≥ 3 t≥3, we have t − 3 ≥ 0 t−3≥0 and t 3 − 9 ≥ 18 t 3

−9≥18, so indeed

( t − 3 ) ( t 3 − 9 ) ≥ 0 (t−3)(t 3

−9)≥0. Hence,

∑ x x 4 + y 2 + z 2 ≤ 1. (2) ∑ x 4

+y

2

+z

2

x

≤1.(2)

Now, we estimate the left-hand side of (1). Note that

x 4 x 4 + y 2 + z 2 = x 6 x 6 + x 2 y 2 + x 2 z 2 , x 4

+y

2

+z

2

x 4

x 6

+x

2

+x

2

x 6

and similarly for the other terms. So,

∑ x 4 x 4 + y 2 + z 2 = ∑ x 6 x 6 + x 2 y 2 + x 2 z 2 . ∑ x 4

+y

2

+z

2

x 4

=∑

x 6

+x

2

+x

2

x 6

By the Cauchy–Schwarz inequality (Titu's lemma), we have:

∑ x 6 x 6 + x 2 y 2 + x 2 z 2 ≥ ( x 3 + y 3 + z 3 ) 2 ∑ ( x 6 + x 2 y 2 + x 2 z 2 ) = ( x 3 + y 3 + z 3 ) 2 x 6 + y 6 + z 6 + 2 ( x 2 y 2 + y 2 z 2 + z 2 x 2 ) . (3) ∑ x 6

+x

2

+x

2

x 6

≥

∑(x 6

+x

2

+x

2

(x 3

+y

3

+z

3

2

x 6

+y

6

+z

6

+2(x

2

+y

2

+z

2

(x 3

+y

3

+z

3

2

.(3)

We claim that

( x 3 + y 3 + z 3 ) 2 ≥ x 6 + y 6 + z 6 + 2 ( x 2 y 2 + y 2 z 2 + z 2 x 2 ) . (x 3

+y

3

+z

3

2

≥x

6

+y

6

+z

6

+2(x

2

+y

2

+z

2

).

Expanding the left-hand side:

( x 3 + y 3 + z 3 ) 2 = x 6 + y 6 + z 6 + 2 ( x 3 y 3 + y 3 z 3 + z 3 x 3 ) . (x 3

+y

3

+z

3

2

=x

6

+y

6

+z

6

+2(x

3

+y

3

+z

3

).

Thus, the inequality is equivalent to

x 3 y 3 + y 3 z 3 + z 3 x 3 ≥ x 2 y 2 + y 2 z 2 + z 2 x 2 . (4) x 3

3

+y

3

+z

3

≥x

2

+y

2

+z

2

.(4)

Let a = x y a=xy, b = y z b=yz, c = z x c=zx. Then a b c = x 2 y 2 z 2 ≥ 1 abc=x 2

2

≥1, and inequality (4) becomes:

a 3 + b 3 + c 3 ≥ a 2 + b 2 + c 2 . a 3

+b

3

+c

3

≥a

2

+b

2

+c

2

We now prove this. By the AM–GM inequality, a 3 + b 3 + c 3 ≥ 3 a b c ≥ 3 a 3

+b

3

+c

3

≥3abc≥3. Also, by the power mean inequality, we have:

( a 3 + b 3 + c 3 3 ) 1 / 3 ≥ ( a 2 + b 2 + c 2 3 ) 1 / 2 , ( 3 a 3

+b

3

+c

3

1/3

≥(

3 a 2

+b

2

+c

2

1/2

which implies

a 3 + b 3 + c 3 ≥ 3 ( a 2 + b 2 + c 2 3 ) 3 / 2 = ( a 2 + b 2 + c 2 ) 3 / 2 3 . a 3

+b

3

+c

3

≥3(

3 a 2

+b

2

+c

2

3/2

3

(a 2

+b

2

+c

2

3/2

Squaring both sides (all positive) gives:

( a 3 + b 3 + c 3 ) 2 ≥ ( a 2 + b 2 + c 2 ) 3 3 . (a 3

+b

3

+c

3

2

≥

3 (a 2

+b

2

+c

2

3

That is,

( a 2 + b 2 + c 2 ) 3 ≤ 3 ( a 3 + b 3 + c 3 ) 2 . (5) (a 2

+b

2

+c

2

3

≤3(a

3

+b

3

+c

3

2

.(5)

On the other hand, since a 3 + b 3 + c 3 ≥ 3 a 3

+b

3

+c

3

≥3, we have

3 ( a 3 + b 3 + c 3 ) 2 ≤ ( a 3 + b 3 + c 3 ) 3 , because ( a 3 + b 3 + c 3 ) 3 ≥ 3 ( a 3 + b 3 + c 3 ) 2 ⇔ a 3 + b 3 + c 3 ≥ 3. 3(a 3

+b

3

+c

3

2

≤(a

3

+b

3

+c

3

,because(a

3

+b

3

+c

3

≥3(a

3

+b

3

+c

3

2

⇔a

3

+b

3

+c

3

≥3.

Combining with (5), we get:

( a 2 + b 2 + c 2 ) 3 ≤ ( a 3 + b 3 + c 3 ) 3 , (a 2

+b

2

+c

2

3

≤(a

3

+b

3

+c

3

so taking cube roots yields a 2 + b 2 + c 2 ≤ a 3 + b 3 + c 3 a 2

+b

2

+c

2

≤a

3

+b

3

+c

3

, as desired.

Therefore, from (3) we obtain

∑ x 4 x 4 + y 2 + z 2 ≥ 1. (6) ∑ x 4

+y

2

+z

2

x 4

≥1.(6)

Combining (2) and (6), we have

∑ x 4 x 4 + y 2 + z 2 ≥ 1 ≥ ∑ x x 4 + y 2 + z 2 , ∑ x 4

+y

2

+z

2

x 4

≥1≥∑

x 4

+y

2

+z

2

x

which proves (1). Hence, the original inequality holds.

Equality occurs when x = y = z = 1 x=y=z=1.

\end{document}

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Difference between revisions of "2005 IMO Problems/Problem 3"

Latest revision as of 02:37, 4 September 2025

@@ Line 1: / Line 1: @@
-==Problem==
+\documentclass{article}
+\usepackage{amsmath}
+\usepackage{amssymb}
+\begin{document}
-Let <math>x, y, z > 0</math> satisfy <math>xyz\ge 1</math>. Prove that <cmath>\frac{x^5-x^2}{x^5+y^2+z^2} + \frac{y^5-y^2}{x^2+y^5+z^2} + \frac{z^5-z^2}{x^2+y^2+z^5} \ge 0.</cmath>
+\section*{Problem}
+Let
+x
+,
+y
+,
+z
+x,y,z be positive real numbers such that
+x
+y
+z
+≥
+xyz≥1. Prove that:
-==Solution==
+x
-{{solution}}
+−
+x
+x
++
+y
++
+z
++
+y
+−
+y
+y
++
+z
++
+x
++
+z
+−
+z
+z
++
+x
++
+y
+≥
+.
+x
+ +y
+ +z
+x
+ −x
+ +
+y
+ +z
+ +x
+y
+ −y
+ +
+z
+ +x
+ +y
+z
+ −z
+ ≥0.
+\section*{Solution}
+We first show that for any positive real numbers
+x
+,
+y
+,
+z
+x,y,z, we have
-==See Also==
+x
+−
+x
+x
++
+y
++
+z
+≥
+x
+−
+x
+x
++
+y
++
+z
+.
+x
+ +y
+ +z
+x
+ −x
+ ≥
+x
+ +y
+ +z
+x
+ −x
+ .
+Indeed, consider the difference:
+\begin{align*}
+&\frac{x^5 - x^2}{x^5 + y^2 + z^2} - \frac{x^4 - x}{x^4 + y^2 + z^2} \
+&= \frac{(x^5 - x^2)(x^4 + y^2 + z^2) - (x^4 - x)(x^5 + y^2 + z^2)}{(x^5 + y^2 + z^2)(x^4 + y^2 + z^2)}.
+\end{align*}
+The numerator simplifies as follows:
+\begin{align*}
+&(x^5 - x^2)(x^4 + y^2 + z^2) - (x^4 - x)(x^5 + y^2 + z^2) \
+&= x^5x^4 + x^5(y^2+z^2) - x^2x^4 - x^2(y^2+z^2) - x^4x^5 - x^4(y^2+z^2) + x x^5 + x(y^2+z^2) \
+&= x^5(y^2+z^2) - x^2(y^2+z^2) - x^4(y^2+z^2) + x(y^2+z^2) \
+&= (y^2+z^2)(x^5 - x^4 - x^2 + x) \
+&= (y^2+z^2)x(x^4 - x^3 - x + 1) \quad \text{(but wait, check: actually, } x^5 - x^4 - x^2 + x = x(x^4 - x^3 - x + 1) \text{? That doesn't factor nicely)}.
+\end{align*}
+Alternatively, note that:
-{{IMO box|year=2005|num-b=2|num-a=4}}
+x
+−
+x
+=
+x
+(
+x
+−
+)
+=
+x
+(
+x
+−
+)
+(
+x
++
+x
++
+)
+,
+x
+−
+x
+=
+x
+(
+x
+−
+)
+=
+x
+(
+x
+−
+)
+(
+x
++
+x
++
+)
+.
+x
+ −x
+ =x
+ (x
+ −1)=x
+ (x−1)(x
+ +x+1),x
+ −x=x(x
+ −1)=x(x−1)(x
+ +x+1).
+So then:
+\begin{align*}
+&\frac{x^5 - x^2}{x^5 + y^2 + z^2} - \frac{x^4 - x}{x^4 + y^2 + z^2} \
+&= \frac{x^2(x-1)(x^2+x+1)}{x^5 + y^2 + z^2} - \frac{x(x-1)(x^2+x+1)}{x^4 + y^2 + z^2} \
+&= x(x-1)(x^2+x+1) \left( \frac{x}{x^5 + y^2 + z^2} - \frac{1}{x^4 + y^2 + z^2} \right).
+\end{align*}
+Now, combine the terms inside the parentheses:
+x
+x
++
+y
++
+z
+−
+x
++
+y
++
+z
+=
+x
+(
+x
++
+y
++
+z
+)
+−
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+=
+(
+x
++
+x
+(
+y
++
+z
+)
+)
+−
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+=
+(
+x
+−
+)
+(
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+.
+x
+ +y
+ +z
+x
+ −
+x
+ +y
+ +z
+ =
+(x
+ +y
+ +z
+ )(x
+ +y
+ +z
+ )
+x(x
+ +y
+ +z
+ )−(x
+ +y
+ +z
+ )
+ =
+(x
+ +y
+ +z
+ )(x
+ +y
+ +z
+ )
+(x
+ +x(y
+ +z
+ ))−(x
+ +y
+ +z
+ )
+ =
+(x
+ +y
+ +z
+ )(x
+ +y
+ +z
+ )
+(x−1)(y
+ +z
+ )
+ .
+Thus, the entire difference becomes:
+x
+(
+x
+−
+)
+(
+x
++
+x
++
+)
+⋅
+(
+x
+−
+)
+(
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+=
+x
+(
+x
+−
+)
+(
+x
++
+x
++
+)
+(
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+≥
+.
+x(x−1)(x
+ +x+1)⋅
+(x
+ +y
+ +z
+ )(x
+ +y
+ +z
+ )
+(x−1)(y
+ +z
+ )
+ =
+(x
+ +y
+ +z
+ )(x
+ +y
+ +z
+ )
+x(x−1)
+ (x
+ +x+1)(y
+ +z
+ )
+ ≥0.
+Hence,
+x
+−
+x
+x
++
+y
++
+z
+≥
+x
+−
+x
+x
++
+y
++
+z
+.
+x
+ +y
+ +z
+x
+ −x
+ ≥
+x
+ +y
+ +z
+x
+ −x
+ .
+Similarly, we have the analogous inequalities for
+y
+y and
+z
+z. Therefore, it suffices to prove that
+x
+−
+x
+x
++
+y
++
+z
++
+y
+−
+y
+y
++
+z
++
+x
++
+z
+−
+z
+z
++
+x
++
+y
+≥
+,
+x
+ +y
+ +z
+x
+ −x
+ +
+y
+ +z
+ +x
+y
+ −y
+ +
+z
+ +x
+ +y
+z
+ −z
+ ≥0,
+or equivalently,
+x
+x
++
+y
++
+z
++
+y
+y
++
+z
++
+x
++
+z
+z
++
+x
++
+y
+≥
+x
+x
++
+y
++
+z
++
+y
+y
++
+z
++
+x
++
+z
+z
++
+x
++
+y
+.
+(1)
+x
+ +y
+ +z
+x
+ +
+y
+ +z
+ +x
+y
+ +
+z
+ +x
+ +y
+z
+ ≥
+x
+ +y
+ +z
+x
+ +
+y
+ +z
+ +x
+y
+ +
+z
+ +x
+ +y
+z
+ .(1)
+Let
+t
+=
+x
++
+y
++
+z
+t=x+y+z. Since
+x
+,
+y
+,
+z
+>
+x,y,z>0 and
+x
+y
+z
+≥
+xyz≥1, by AM–GM we have
+t
+≥
+x
+y
+z
+≥
+t≥3
+xyz
+ ≥3. Also, note that
+x
+y
++
+y
+z
++
+z
+x
+≤
+t
+xy+yz+zx≤
+t
+  and
+x
++
+y
++
+z
+≥
+t
+x
+ +y
+ +z
+ ≥
+t
+ .
+Now, we estimate the right-hand side of (1). By the Cauchy–Schwarz inequality, we have:
+(
+x
++
+y
++
+z
+)
+≤
+(
+x
++
+y
++
+z
+)
+(
++
+y
++
+z
+)
+,
+(x
+ +y
+ +z
+ )
+ ≤(x
+ +y
+ +z
+ )(1+y
+ +z
+ ),
+since
+(
+x
++
+y
++
+z
+)
+=
+(
+x
+⋅
++
+y
+⋅
+y
++
+z
+⋅
+z
+)
+≤
+(
+x
++
+y
++
+z
+)
+(
++
+y
++
+z
+)
+=
+(
+x
++
+y
++
+z
+)
+(
++
+y
++
+z
+)
+.
+(x
+ +y
+ +z
+ )
+ =(x
+ ⋅1+y⋅y+z⋅z)
+ ≤(x
+ +y
+ +z
+ )(1
+ +y
+ +z
+ )=(x
+ +y
+ +z
+ )(1+y
+ +z
+ ).
+It follows that
+x
++
+y
++
+z
+≤
++
+y
++
+z
+(
+x
++
+y
++
+z
+)
+,
+x
+ +y
+ +z
+ ≤
+(x
+ +y
+ +z
+ )
++y
+ +z
+ ,
+and multiplying by
+x
+x (which is positive) gives:
+x
+x
++
+y
++
+z
+≤
+x
+(
++
+y
++
+z
+)
+(
+x
++
+y
++
+z
+)
+.
+x
+ +y
+ +z
+x
+ ≤
+(x
+ +y
+ +z
+ )
+x(1+y
+ +z
+ )
+ .
+Similarly,
+y
+y
++
+z
++
+x
+≤
+y
+(
++
+z
++
+x
+)
+(
+x
++
+y
++
+z
+)
+,
+z
+z
++
+x
++
+y
+≤
+z
+(
++
+x
++
+y
+)
+(
+x
++
+y
++
+z
+)
+.
+y
+ +z
+ +x
+y
+ ≤
+(x
+ +y
+ +z
+ )
+y(1+z
+ +x
+ )
+ ,
+z
+ +x
+ +y
+z
+ ≤
+(x
+ +y
+ +z
+ )
+z(1+x
+ +y
+ )
+ .
+Summing these, we obtain:
+∑
+x
+x
++
+y
++
+z
+≤
+(
+x
++
+y
++
+z
+)
+[
+∑
+x
++
+∑
+x
+(
+y
++
+z
+)
+]
+.
+∑
+x
+ +y
+ +z
+x
+ ≤
+(x
+ +y
+ +z
+ )
+ [∑x+∑x(y
+ +z
+ )].
+Now, note that
+∑
+x
+(
+y
++
+z
+)
+=
+∑
+(
+x
+y
++
+x
+z
+)
+=
+(
+x
+y
++
+x
+z
+)
++
+(
+y
+z
++
+y
+x
+)
++
+(
+z
+x
++
+z
+y
+)
+=
+(
+x
++
+y
++
+z
+)
+(
+x
+y
++
+y
+z
++
+z
+x
+)
+−
+x
+y
+z
+.
+∑x(y
+ +z
+ )=∑(xy
+ +xz
+ )=(xy
+ +xz
+ )+(yz
+ +yx
+ )+(zx
+ +zy
+ )=(x+y+z)(xy+yz+zx)−3xyz.
+Thus,
+∑
+x
+x
++
+y
++
+z
+≤
+t
++
+t
+(
+x
+y
++
+y
+z
++
+z
+x
+)
+−
+x
+y
+z
+(
+x
++
+y
++
+z
+)
+.
+∑
+x
+ +y
+ +z
+x
+ ≤
+(x
+ +y
+ +z
+ )
+t+t(xy+yz+zx)−3xyz
+ .
+Since
+x
+y
+z
+≥
+xyz≥1, we have
+−
+x
+y
+z
+≤
+−
+−3xyz≤−3. Also,
+x
+y
++
+y
+z
++
+z
+x
+≤
+t
+xy+yz+zx≤
+t
+  and
+x
++
+y
++
+z
+≥
+t
+x
+ +y
+ +z
+ ≥
+t
+ , so
+(
+x
++
+y
++
+z
+)
+≥
+(
+t
+)
+=
+t
+.
+(x
+ +y
+ +z
+ )
+ ≥(
+t
+ )
+ =
+t
+ .
+Therefore,
+∑
+x
+x
++
+y
++
+z
+≤
+t
++
+t
+⋅
+t
+−
+(
+t
+/
+)
+=
+t
++
+t
+−
+t
+/
+=
+(
+t
++
+t
+−
+)
+t
+=
+t
++
+t
+−
+t
+=
+t
++
+t
+−
+t
+.
+∑
+x
+ +y
+ +z
+x
+ ≤
+(t
+ /3)
+t+t⋅
+t
+ −3
+ =
+t
+ /9
+t+
+t
+ −3
+ =
+t
+(t+
+t
+ −3)
+ =
+t
+t+3t
+ −27
+ =
+t
+t
+ +9t−27
+ .
+We now show that
+t
++
+t
+−
+t
+≤
+.
+t
+t
+ +9t−27
+ ≤1.
+This is equivalent to
+t
++
+t
+−
+≤
+t
+⇔
+t
+−
+t
+−
+t
++
+≥
+.
+t
+ +9t−27≤t
+ ⇔t
+ −3t
+ −9t+27≥0.
+Factor the left-hand side:
+t
+−
+t
+−
+t
++
+=
+(
+t
+−
+)
+(
+t
+−
+)
+.
+t
+ −3t
+ −9t+27=(t−3)(t
+ −9).
+For
+t
+≥
+t≥3, we have
+t
+−
+≥
+t−3≥0 and
+t
+−
+≥
+t
+ −9≥18, so indeed
+(
+t
+−
+)
+(
+t
+−
+)
+≥
+(t−3)(t
+ −9)≥0. Hence,
+∑
+x
+x
++
+y
++
+z
+≤
+.
+(2)
+∑
+x
+ +y
+ +z
+x
+ ≤1.(2)
+Now, we estimate the left-hand side of (1). Note that
+x
+x
++
+y
++
+z
+=
+x
+x
++
+x
+y
++
+x
+z
+,
+x
+ +y
+ +z
+x
+ =
+x
+ +x
+ y
+ +x
+ z
+x
+ ,
+and similarly for the other terms. So,
+∑
+x
+x
++
+y
++
+z
+=
+∑
+x
+x
++
+x
+y
++
+x
+z
+.
+∑
+x
+ +y
+ +z
+x
+ =∑
+x
+ +x
+ y
+ +x
+ z
+x
+ .
+By the Cauchy–Schwarz inequality (Titu's lemma), we have:
+∑
+x
+x
++
+x
+y
++
+x
+z
+≥
+(
+x
++
+y
++
+z
+)
+∑
+(
+x
++
+x
+y
++
+x
+z
+)
+=
+(
+x
++
+y
++
+z
+)
+x
++
+y
++
+z
++
+(
+x
+y
++
+y
+z
++
+z
+x
+)
+.
+(3)
+∑
+x
+ +x
+ y
+ +x
+ z
+x
+ ≥
+∑(x
+ +x
+ y
+ +x
+ z
+ )
+(x
+ +y
+ +z
+ )
+ =
+x
+ +y
+ +z
+ +2(x
+ y
+ +y
+ z
+ +z
+ x
+ )
+(x
+ +y
+ +z
+ )
+ .(3)
+We claim that
+(
+x
++
+y
++
+z
+)
+≥
+x
++
+y
++
+z
++
+(
+x
+y
++
+y
+z
++
+z
+x
+)
+.
+(x
+ +y
+ +z
+ )
+ ≥x
+ +y
+ +z
+ +2(x
+ y
+ +y
+ z
+ +z
+ x
+ ).
+Expanding the left-hand side:
+(
+x
++
+y
++
+z
+)
+=
+x
++
+y
++
+z
++
+(
+x
+y
++
+y
+z
++
+z
+x
+)
+.
+(x
+ +y
+ +z
+ )
+ =x
+ +y
+ +z
+ +2(x
+ y
+ +y
+ z
+ +z
+ x
+ ).
+Thus, the inequality is equivalent to
+x
+y
++
+y
+z
++
+z
+x
+≥
+x
+y
++
+y
+z
++
+z
+x
+.
+(4)
+x
+ y
+ +y
+ z
+ +z
+ x
+ ≥x
+ y
+ +y
+ z
+ +z
+ x
+ .(4)
+Let
+a
+=
+x
+y
+a=xy,
+b
+=
+y
+z
+b=yz,
+c
+=
+z
+x
+c=zx. Then
+a
+b
+c
+=
+x
+y
+z
+≥
+abc=x
+ y
+ z
+ ≥1, and inequality (4) becomes:
+a
++
+b
++
+c
+≥
+a
++
+b
++
+c
+.
+a
+ +b
+ +c
+ ≥a
+ +b
+ +c
+ .
+We now prove this. By the AM–GM inequality,
+a
++
+b
++
+c
+≥
+a
+b
+c
+≥
+a
+ +b
+ +c
+ ≥3abc≥3. Also, by the power mean inequality, we have:
+(
+a
++
+b
++
+c
+)
+/
+≥
+(
+a
++
+b
++
+c
+)
+/
+,
+(
+a
+ +b
+ +c
+ )
+/3
+ ≥(
+a
+ +b
+ +c
+ )
+/2
+ ,
+which implies
+a
++
+b
++
+c
+≥
+(
+a
++
+b
++
+c
+)
+/
+=
+(
+a
++
+b
++
+c
+)
+/
+.
+a
+ +b
+ +c
+ ≥3(
+a
+ +b
+ +c
+ )
+/2
+ =
+(a
+ +b
+ +c
+ )
+/2
+ .
+Squaring both sides (all positive) gives:
+(
+a
++
+b
++
+c
+)
+≥
+(
+a
++
+b
++
+c
+)
+.
+(a
+ +b
+ +c
+ )
+ ≥
+(a
+ +b
+ +c
+ )
+ .
+That is,
+(
+a
++
+b
++
+c
+)
+≤
+(
+a
++
+b
++
+c
+)
+.
+(5)
+(a
+ +b
+ +c
+ )
+ ≤3(a
+ +b
+ +c
+ )
+ .(5)
+On the other hand, since
+a
++
+b
++
+c
+≥
+a
+ +b
+ +c
+ ≥3, we have
+(
+a
++
+b
++
+c
+)
+≤
+(
+a
++
+b
++
+c
+)
+,
+because
+(
+a
++
+b
++
+c
+)
+≥
+(
+a
++
+b
++
+c
+)
+⇔
+a
++
+b
++
+c
+≥
+.
+(a
+ +b
+ +c
+ )
+ ≤(a
+ +b
+ +c
+ )
+ ,because(a
+ +b
+ +c
+ )
+ ≥3(a
+ +b
+ +c
+ )
+ ⇔a
+ +b
+ +c
+ ≥3.
+Combining with (5), we get:
+(
+a
++
+b
++
+c
+)
+≤
+(
+a
++
+b
++
+c
+)
+,
+(a
+ +b
+ +c
+ )
+ ≤(a
+ +b
+ +c
+ )
+ ,
+so taking cube roots yields
+a
++
+b
++
+c
+≤
+a
++
+b
++
+c
+a
+ +b
+ +c
+ ≤a
+ +b
+ +c
+ , as desired.
+Therefore, from (3) we obtain
+∑
+x
+x
++
+y
++
+z
+≥
+.
+(6)
+∑
+x
+ +y
+ +z
+x
+ ≥1.(6)
+Combining (2) and (6), we have
+∑
+x
+x
++
+y
++
+z
+≥
+≥
+∑
+x
+x
++
+y
++
+z
+,
+∑
+x
+ +y
+ +z
+x
+ ≥1≥∑
+x
+ +y
+ +z
+x
+ ,
+which proves (1). Hence, the original inequality holds.
+Equality occurs when
+x
+=
+y
+=
+z
+=
+x=y=z=1.
+\end{document}