Difference between revisions of "2001 IMO Shortlist Problems/G1"

Revision as of 15:05, 12 December 2011

Problem

Let $A_1$ be the center of the square inscribed in acute triangle $ABC$ with two vertices of the square on side $BC$ . Thus one of the two remaining vertices of the square is on side $AB$ and the other is on $AC$ . Points $B_1,\ C_1$ are defined in a similar way for inscribed squares with two vertices on sides $AC$ and $AB$ , respectively. Prove that lines $AA_1,\ BB_1,\ CC_1$ are concurrent.

Solution

Let $BC=a$ , $CA=b$ , $AB=c$ , $\angle BAC=\alpha$ , $\angle CBA=\beta$ , and $\angle ACB=\gamma$ . Let $A_2$ be the point on the other side of $BC$ than $A$ such that $BA_2C$ is an isosceles right triangle. Define $B_2$ and $C_2$ similarly. Let $E$ and $F$ be the points on $AB$ and $CA$ that are the vertices of the square centered at $A_1$ . We then have that $EA_1F$ is also an isosceles right triangle. It's clear that $EF$ is parallel to $BC$ , so $\triangle AEF\sim \triangle ABC$ and $\triangle A_1EF\sim \triangle A_2BC$ . The ratio of similarity of both relations is $\frac{EF}{BC}$ , which implies that quadrilaterals $AEA_1F$ and $ABA_2C$ are similar. Therefore $\angle BAA_2=\angle EAA_1$ and $\angle CAA_2=EAA_1$ . It then follows that $A$ , $A_1$ , and $A_2$ are collinear. Similarly $B$ , $B_1$ , and $B_2$ are collinear, as are $C$ , $C_1$ , and $C_2$ . It therefore suffices to show that $AA_2$ , $BB_2$ , and $CC_2$ are concurrent.

Let $AC_2=s$ and $CC_2=d$ , for positive reals $s$ and $d$ . Also let $\angle ACC_2=\theta$ and $\angle BCC_2=\phi$ . Note that $\angle C_2AC=\angle C_2AB+\angle BAC=45^{\circ}+\alpha$ , and likewise $\angle C_2BC = 45^{\circ}+\beta$ . It then follows from the Law of Sines on triangles $ACC_2$ and $BCC_2$ that

$\frac{d}{\sin{(\alpha+45^{\circ})}}=\frac{s}{\sin{\theta}}$

and

$\frac{d}{\sin{(\beta+45^{\circ})}}=\frac{s}{\sin{\phi}}$

Solving for $\sin{\theta}$ and $\sin{\phi}$ gives that

$\sin{\theta}=\frac{s\sin{(\alpha+45^{\circ})}}{d}$

and

$\sin{\phi}=\frac{s\sin{(\beta+45^{\circ})}}{d}$

Therefore

$\frac{\sin{\theta}}{\sin{\phi}}=\frac{\sin\angle ACC_2}{\sin\angle BCC_2}=\frac{\sin{(\alpha+45^{\circ})}}{\sin{(\beta+45^{\circ})}}$

Similar lines of reasoning show that

$\frac{\sin\angle BAA_2}{\sin\angle CAA_2}=\frac{\sin{(\beta+45^{\circ})}}{\sin{(\gamma+45^{\circ})}}$

and

$\frac{\sin\angle CBB_2}{\sin\angle ABB_2}=\frac{\sin{(\gamma+45^{\circ})}}{\sin{(\alpha+45^{\circ})}}$

An application of the trigonometric version of Ceva's Theorem shows that $AA_2$ , $BB_2$ , and $CC_2$ are concurrent, which shoes that $AA_1$ , $BB_1$ , and $CC_1$ are concurrent.

Resources

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 == Solution ==
-{{solution}}
+Let <math>BC=a</math>, <math>CA=b</math>, <math>AB=c</math>, <math>\angle BAC=\alpha</math>, <math>\angle CBA=\beta</math>, and <math>\angle ACB=\gamma</math>. Let <math>A_2</math> be the point on the other side of <math>BC</math> than <math>A</math> such that <math>BA_2C</math> is an isosceles right triangle. Define <math>B_2</math> and <math>C_2</math> similarly. Let <math>E</math> and <math>F</math> be the points on <math>AB</math> and <math>CA</math> that are the vertices of the square centered at <math>A_1</math>. We then have that <math>EA_1F</math> is also an isosceles right triangle. It's clear that <math>EF</math> is parallel to <math>BC</math>, so <math>\triangle AEF\sim \triangle ABC</math> and <math>\triangle A_1EF\sim \triangle A_2BC</math>. The ratio of similarity of both relations is <math>\frac{EF}{BC}</math>, which implies that quadrilaterals <math>AEA_1F</math> and <math>ABA_2C</math> are similar. Therefore <math>\angle BAA_2=\angle EAA_1</math> and <math>\angle CAA_2=EAA_1</math>. It then follows that <math>A</math>, <math>A_1</math>, and <math>A_2</math> are collinear. Similarly <math>B</math>, <math>B_1</math>, and <math>B_2</math> are collinear, as are <math>C</math>, <math>C_1</math>, and <math>C_2</math>. It therefore suffices to show that <math>AA_2</math>, <math>BB_2</math>, and <math>CC_2</math> are concurrent.
+Let <math>AC_2=s</math> and <math>CC_2=d</math>, for positive reals <math>s</math> and <math>d</math>. Also let <math>\angle ACC_2=\theta</math> and <math>\angle BCC_2=\phi</math>. Note that <math>\angle C_2AC=\angle C_2AB+\angle BAC=45^{\circ}+\alpha</math>, and likewise <math>\angle C_2BC = 45^{\circ}+\beta</math>. It then follows from the Law of Sines on triangles <math>ACC_2</math> and <math>BCC_2</math> that
+<cmath>\frac{d}{\sin{(\alpha+45^{\circ})}}=\frac{s}{\sin{\theta}}</cmath>
+and
+<cmath>\frac{d}{\sin{(\beta+45^{\circ})}}=\frac{s}{\sin{\phi}}</cmath>
+Solving for <math>\sin{\theta}</math> and <math>\sin{\phi}</math> gives that
+<cmath>\sin{\theta}=\frac{s\sin{(\alpha+45^{\circ})}}{d}</cmath>
+and
+<cmath>\sin{\phi}=\frac{s\sin{(\beta+45^{\circ})}}{d}</cmath>
+Therefore
+<cmath>\frac{\sin{\theta}}{\sin{\phi}}=\frac{\sin\angle ACC_2}{\sin\angle BCC_2}=\frac{\sin{(\alpha+45^{\circ})}}{\sin{(\beta+45^{\circ})}}</cmath>
+Similar lines of reasoning show that
+<cmath>\frac{\sin\angle BAA_2}{\sin\angle CAA_2}=\frac{\sin{(\beta+45^{\circ})}}{\sin{(\gamma+45^{\circ})}}</cmath>
+and
+<cmath>\frac{\sin\angle CBB_2}{\sin\angle ABB_2}=\frac{\sin{(\gamma+45^{\circ})}}{\sin{(\alpha+45^{\circ})}}</cmath>
+An application of the trigonometric version of Ceva's Theorem shows that <math>AA_2</math>, <math>BB_2</math>, and <math>CC_2</math> are concurrent, which shoes that <math>AA_1</math>, <math>BB_1</math>, and <math>CC_1</math> are concurrent.
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Difference between revisions of "2001 IMO Shortlist Problems/G1"

Revision as of 15:05, 12 December 2011

Problem

Solution

Resources