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1994 USAMO Problems/Problem 3: Difference between revisions

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==Problem==
==Problem==
A convex hexagon <math>ABCDEF</math> is inscribed in a circle such that <math>AB=CD=EF</math> and diagonals <math>AD,BE</math>, and <math>CF</math> are concurrent. Let <math>P</math> be the intersection of <math>AD</math> and <math>CE</math>. Prove that <math>\frac{CP}{CE}=(\frac{AC}{CE})^2</math>.
A convex hexagon <math>ABCDEF</math> is inscribed in a circle such that <math>AB=CD=EF</math> and diagonals <math>AD,BE</math>, and <math>CF</math> are concurrent. Let <math>P</math> be the intersection of <math>AD</math> and <math>CE</math>. Prove that <math>\frac{CP}{PE}=(\frac{AC}{CE})^2</math>.


==Solution==
==Solution==

Revision as of 15:34, 30 May 2014

Problem

A convex hexagon $ABCDEF$ is inscribed in a circle such that $AB=CD=EF$ and diagonals $AD,BE$, and $CF$ are concurrent. Let $P$ be the intersection of $AD$ and $CE$. Prove that $\frac{CP}{PE}=(\frac{AC}{CE})^2$.

Solution

Let the diagonals $AD$, $BE$, $CF$ meet at $Q$.

First, let's show that the triangles $\triangle AEC$ and $\triangle QED$ are similar.

[asy] pair A,B,C,D,E,F,P,Q; A=(-0.96,0.28); B=(-0.352,0.936); C=(0,1); D=(4/5,3/5); E=(4/5,-3/5); F=(0,-1); P=IntersectionPoint(A--D,C--E); Q=IntersectionPoint(A--D,C--F); draw(A--B); draw(B--C); draw(C--D); draw(D--E,green); draw(E--F); draw(F--A); draw(A--C,red); draw(A--Q); draw(A--E,red); draw(B--Q); draw(C--E,red); draw(C--F); draw(Q--E,green); draw(Q--D,green); draw(circle((0,0),1)); label("\(A\)",A,W); label("\(B\)",B,N); label("\(C\)",C,N); label("\(D\)",D,NE); label("\(E\)",E,SE); label("\(F\)",F,S); label("\(P\)",(0.3,0.8),S); label("\(Q\)",(-0.15,0.4),S); [/asy]

$\angle ACE=\angle ADE$ because $A$,$C$,$D$ and $E$ all lie on the circle, and $\angle ADE=\angle QDE$. $\angle AEB=\angle CED$ because $AB=CD$, and $A$,$B$,$C$,$D$ and $E$ all lie on the circle. Then,

$\angle AEB=\angle CED \rightarrow \angle AEB+\angle BEC=\angle CED+\angle BEC \rightarrow \angle AEC=\angle QED$

Therefore, $\triangle AEC$ and $\triangle QED$ are similar, so $AC/CE=QD/DE$.

Next, let's show that $\triangle AEC$ and $\triangle CDQ$ are similar.

[asy] pair A,B,C,D,E,F,P,Q; A=(-0.96,0.28); B=(-0.352,0.936); C=(0,1); D=(4/5,3/5); E=(4/5,-3/5); F=(0,-1); P=IntersectionPoint(A--D,C--E); Q=IntersectionPoint(A--D,C--F); draw(A--B); draw(B--C); draw(C--D,green); draw(D--E); draw(E--F); draw(F--A); draw(A--C,red); draw(A--Q); draw(A--E,red); draw(B--E); draw(C--E,red); draw(Q--F); draw(Q--C,green); draw(Q--D,green); draw(circle((0,0),1)); label("\(A\)",A,W); label("\(B\)",B,N); label("\(C\)",C,N); label("\(D\)",D,NE); label("\(E\)",E,SE); label("\(F\)",F,S); label("\(P\)",(0.3,0.8),S); label("\(Q\)",(-0.15,0.4),S); [/asy]

$\angle AEC=\angle ADC$ because $A$,$C$,$D$ and $E$ all lie on the circle, and $\angle ADC=\angle CDQ$. $\angle EAD=\angle ECD$ because $A$,$C$,$D$ and $E$ all lie on the circle. $\angle DAC=\angle ECF$ because $CD=EF$, and $A$,$C$,$D$,$E$ and $F$ all lie on the circle. Then,

$\angle EAC=\angle EAD+\angle DAC=\angle ECD+\angle ECF=\angle DCY$

Therefore, $\triangle AEC$ and $\triangle CDQ$ are similar, so $AC/CE=CQ/QD$.

Lastly, let's show that $\triangle CPQ$ and $\triangle EPD$ are similar.

[asy] pair A,B,C,D,E,F,P,Q; A=(-0.96,0.28); B=(-0.352,0.936); C=(0,1); D=(4/5,3/5); E=(4/5,-3/5); F=(0,-1); P=IntersectionPoint(A--D,C--E); Q=IntersectionPoint(A--D,C--F); draw(A--B); draw(B--C); draw(C--D); draw(D--E,green); draw(E--F); draw(F--A); draw(A--C); draw(A--Q); draw(A--E); draw(B--E); draw(P--E,green); draw(Q--F); draw(C--P,red); draw(Q--P,red); draw(C--Q,red); draw(D--P,green); draw(circle((0,0),1)); label("\(A\)",A,W); label("\(B\)",B,N); label("\(C\)",C,N); label("\(D\)",D,NE); label("\(E\)",E,SE); label("\(F\)",F,S); label("\(P\)",(0.3,0.8),S); label("\(Q\)",(-0.15,0.4),S); [/asy]

Because $CD=EF$ and $C$,$D$,$E$ and $F$ all lie on the circle, $CF$ is parallel to $DE$. So, $\triangle CPQ$ and $\triangle EPD$ are similar, and $CQ/DE=CP/PE$.

Putting it all together, $CP/PE=CQ/DE=AC/CE\cdot QD/DE=(AC/CE)^2$.

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