Difference between revisions of "2021 USAMO Problems/Problem 6"

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(Solution)
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<math>\triangle XYZ</math> is <math>\triangle X'Y'Z'</math> translated on <math>– \vec {V}.</math>
 
<math>\triangle XYZ</math> is <math>\triangle X'Y'Z'</math> translated on <math>– \vec {V}.</math>
  
It is known (see diagram) that circumcenter of triangle coincide with orthocenter of the medial triangle. Therefore  orthocenter <math>H</math> of <math>\triangle XYZ</math> is circumcenter of <math>\triangle B'D'F'</math> translated on <math>– \vec {V}.</math> It is the midpoint of segment <math>OO'</math> connected circumcenters of <math>\triangle B'D'F'</math> and <math>\triangle A'C'E'.</math>
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It is known (see diagram) that circumcenter of triangle coincide with orthocenter of the medial triangle. Therefore  orthocenter <math>H</math> of <math>\triangle XYZ</math> is circumcenter of <math>\triangle B'D'F'</math> translated on <math>– \vec {V}.</math>
  
According to the definition of points <math>A', C', E', ABCE', CDEA',</math> and <math>AFEC'</math> are parallelograms <math>\implies</math>
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It is the midpoint of segment <math>OO'</math> connected circumcenters of <math>\triangle B'D'F'</math> and <math>\triangle A'C'E'.</math>
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According to the definition of points <math>A', C', E',</math> quadrangle <math>ABCE', CDEA',</math> and <math>AFEC'</math> are parallelograms. Hence
 
<cmath>AC' = FE, AE' = BC, CE' = AB, CA' = DE, EA' = CD, EC' = AF \implies</cmath>
 
<cmath>AC' = FE, AE' = BC, CE' = AB, CA' = DE, EA' = CD, EC' = AF \implies</cmath>
<cmath>AC' \cdot AE' = CE' \cdot CA' = EA' \cdot EC' \implies</cmath> Power of points A,C, and E with respect circumcircle \triangle A'C'E' is equal, hence distances between these points and circumcenter of \triangle A'C'E' are the same \implies circumcenters of constructed triangles coincide with given circumcenters.
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<cmath>AC' \cdot AE' = CE' \cdot CA' = EA' \cdot EC' = AB \cdot DE \implies</cmath> Power of points A,C, and E with respect circumcircle <math>\triangle A'C'E'</math> is equal, hence distances between these points and circumcenter of <math>\triangle A'C'E'</math> are the same. Therefore circumcenters of constructed triangles coincide with given circumcenters.
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'''vladimir.shelomovskii@gmail.com, vvsss'''

Revision as of 09:06, 15 September 2022

Problem 6

Let $ABCDEF$ be a convex hexagon satisfying $\overline{AB} \parallel \overline{DE}$, $\overline{BC} \parallel \overline{EF}$, $\overline{CD} \parallel \overline{FA}$, and\[AB \cdot DE = BC \cdot EF = CD \cdot FA.\]Let $X$, $Y$, and $Z$ be the midpoints of $\overline{AD}$, $\overline{BE}$, and $\overline{CF}$. Prove that the circumcenter of $\triangle ACE$, the circumcenter of $\triangle BDF$, and the orthocenter of $\triangle XYZ$ are collinear.

Solution

2021 USAMO 6b.png
2021 USAMO 6c.png
2021 USAMO 6a.png

We construct two equal triangles, prove that triangle $XYZ$ is the same as medial triangle of both this triangles. We use property of medial triangle and prove that circumcenters of constructed triangles coincide with given circumcenters.

Denote $A' =  C + E – D, B' = D + F – E, C' =  A+ E – F,$ $D' =  F+ B – A, E' =  A + C – B, F' =  B+ D – C.$ Then $A' – D'  =  C + E – D –  ( F+ B – A) = (A + C + E ) – (B+ D + F).$

Denote $D' – A' = 2\vec V.$

Symilarly we get $B' – E' = F' – C' =  D' – A'  \implies$ $\triangle A'C'E' = \triangle D'F'B'.$

The translation vector maps $\triangle A'C'E'$ into $\triangle D'F'B'$ is $2\vec {V.}$ $X = \frac {A+D}{2} =  \frac { (A+ E – F) + (D + F – E)}{2} =  \frac {C' + B'}{2} = \frac {E' + F'}{2},$

so $X$ is midpoint of $AD, B'C',$ and $E'F'.$ Symilarly $Y$ is the midpoint of $BE, A'F',$ and $C'D', Z$ is the midpoint of $CF, A'B',$ and $D'E'.$ $Z + V =  \frac {A' + B'}{2}+ \frac {D' – A'}{2} =  \frac {B' + D'}{2} = Z'$ is the midpoint of $B'D'.$

Symilarly $X' = X + V$ is the midpoint of $B'F',Y'= Y + V$ is the midpoint of $D'F'.$

Therefore $\triangle X'Y'Z'$ is the medial triangle of $\triangle B'D'F'.$

$\triangle XYZ$ is $\triangle X'Y'Z'$ translated on $– \vec {V}.$

It is known (see diagram) that circumcenter of triangle coincide with orthocenter of the medial triangle. Therefore orthocenter $H$ of $\triangle XYZ$ is circumcenter of $\triangle B'D'F'$ translated on $– \vec {V}.$

It is the midpoint of segment $OO'$ connected circumcenters of $\triangle B'D'F'$ and $\triangle A'C'E'.$

According to the definition of points $A', C', E',$ quadrangle $ABCE', CDEA',$ and $AFEC'$ are parallelograms. Hence \[AC' = FE, AE' = BC, CE' = AB, CA' = DE, EA' = CD, EC' = AF \implies\] \[AC' \cdot AE' = CE' \cdot CA' = EA' \cdot EC' = AB \cdot DE \implies\] Power of points A,C, and E with respect circumcircle $\triangle A'C'E'$ is equal, hence distances between these points and circumcenter of $\triangle A'C'E'$ are the same. Therefore circumcenters of constructed triangles coincide with given circumcenters.

vladimir.shelomovskii@gmail.com, vvsss