Difference between revisions of "2007 BMO Problems/Problem 1"

Revision as of 23:41, 23 October 2012

Problem

(Albania) Let $ABCD$ be a convex quadrilateral with $AB=BC=CD$ , $AC \neqBD$ (Error compiling LaTeX. Unknown error_msg), and let $E$ be the intersection point of its diagonals. Prove that $AE=DE$ if and only if $\angle BAD+\angle ADC = 120^{\circ}$ .

Solution

Since $AB = BC$ , $\angle BAC = \angle ACB$ , and similarly, $\angle CBD = \angle BDC$ . Since $\angle CEB = \angle AED$ , by considering triangles $CEB, AED$ we have $\angle BAC + \angle BDC = \angle ECB + \angle CBE = \angle EAD + \angle EDA$ . It follows that $2 ( \angle BAC + \angle BDC ) = \angle BAD + \angle ADC$ .

Now, by the Law of Sines,

$\frac{AE}{DE} = \frac{AE}{EB} \cdot \frac{EB}{EC} \cdot \frac{EC}{DE} = \frac{\sin (\pi - 2\alpha - \beta)}{\sin \alpha} \cdot \frac{\sin \alpha}{\sin \beta} \cdot \frac{\sin \beta}{\sin (\pi - 2\beta - \alpha)} = \frac{\sin (\pi - 2\alpha - \beta)}{\sin (\pi - 2\beta - \alpha)}$ .

It follows that $AE = DE$ if and only if

$\sin (\pi - 2\alpha - \beta) = \sin (\pi - 2\beta - \alpha)$ .

Since $0 < \alpha, \beta < \pi/2$ ,

$0 < (\pi - 2\alpha - \beta) + (\pi - 2\beta - \alpha) < 2\pi$ ,

and

$-\pi < (\pi - 2\alpha - \beta) - (\pi - 2\beta - \alpha) < \pi$ .

From these inequalities, we see that $\sin (\pi - 2\alpha - \beta ) = \sin (\pi - 2\beta - \alpha)$ if and only if $(\pi - 2\alpha - \beta) = (\pi - 2\beta - \alpha)$ (i.e., $\alpha = \beta$ ) or $(\pi - 2\alpha - \beta) + (\pi - 2\beta - \alpha) = \pi$ (i.e., $3(\alpha + \beta) = \pi$ ). But if $\alpha = \beta$ , then triangles $ABC, BCD$ are congruent and $AC = BD$ , a contradiction. Thus we conclude that $AE = DE$ if and only if $\alpha + \beta = \pi/3$ , Q.E.D.

Alternate solutions are always welcome. If you have a different, elegant solution to this problem, please add it to this page.

Resources

@@ Line 2: / Line 2: @@
 (''Albania'')
-Let <math> \displaystyle ABCD </math> be a convex quadrilateral with <math> \displaystyle AB=BC=CD </math>, <math> \displaystyle AC \neq \displaystyle BD </math>, and let <math> \displaystyle E </math> be the intersection point of its diagonals. Prove that <math> \displaystyle AE=DE </math> if and only if <math> \angle BAD+\angle ADC = 120^{\circ} </math>.
+Let <math>ABCD </math> be a convex quadrilateral with <math>AB=BC=CD </math>, <math>AC \neqBD </math>, and let <math>E </math> be the intersection point of its diagonals. Prove that <math>AE=DE </math> if and only if <math> \angle BAD+\angle ADC = 120^{\circ} </math>.
 == Solution ==
-Since <math> \displaystyle AB = BC </math>, <math> \angle BAC = \angle ACB </math>, and similarly, <math> \angle CBD = \angle BDC </math>.  Since <math> \angle CEB = \angle AED </math>, by consdering triangles <math> \displaystyle CEB, AED </math> we have <math> \angle BAC + \angle BDC = \angle ECB + \angle CBE = \angle EAD + \angle EDA </math>.  It follows that <math> 2 ( \angle BAC + \angle BDC ) = \angle BAD + \angle ADC </math>.
+Since <math>AB = BC </math>, <math> \angle BAC = \angle ACB </math>, and similarly, <math> \angle CBD = \angle BDC </math>.  Since <math> \angle CEB = \angle AED </math>, by considering triangles <math>CEB, AED </math> we have <math> \angle BAC + \angle BDC = \angle ECB + \angle CBE = \angle EAD + \angle EDA </math>.  It follows that <math> 2 ( \angle BAC + \angle BDC ) = \angle BAD + \angle ADC </math>.
 Now, by the [[Law of Sines]],
@@ Line 14: / Line 14: @@
 </math>.
 </center>
-It follows that <math> \displaystyle AE = DE </math> if and only if
+It follows that <math>AE = DE </math> if and only if
 <center>
-<math> \displaystyle \sin (\pi - 2\alpha - \beta) = \sin (\pi - 2\beta - \alpha) </math>.
+<math>\sin (\pi - 2\alpha - \beta) = \sin (\pi - 2\beta - \alpha) </math>.
 </center>
-Since <math> \displaystyle 0 < \alpha, \beta < \pi/2 </math>,
+Since <math>0 < \alpha, \beta < \pi/2 </math>,
-<center><math> \displaystyle 0 < (\pi - 2\alpha - \beta) + (\pi - 2\beta - \alpha) < 2\pi </math>,
+<center><math>0 < (\pi - 2\alpha - \beta) + (\pi - 2\beta - \alpha) < 2\pi </math>,
 </center>
 and
-<center><math> \displaystyle -\pi < (\pi - 2\alpha - \beta) - (\pi - 2\beta - \alpha) < \pi </math>.
+<center><math>-\pi < (\pi - 2\alpha - \beta) - (\pi - 2\beta - \alpha) < \pi </math>.
 </center>
-From these inequalities, we see that <math> \displaystyle \sin (\pi - 2\alpha - \beta ) = \sin (\pi - 2\beta - \alpha) </math> if and only if <math> \displaystyle (\pi - 2\alpha - \beta) = (\pi - 2\beta - \alpha) </math> (i.e., <math> \displaystyle \alpha = \beta </math>) or <math> \displaystyle (\pi - 2\alpha - \beta) + (\pi - 2\beta - \alpha) = \pi </math> (i.e., <math> \displaystyle 3(\alpha + \beta) = \pi </math>).  But if <math> \displaystyle \alpha = \beta </math>, then triangles <math> \displaystyle ABC, BCD </math> are congruent and <math> \displaystyle AC = BD </math>, a contradiction.  Thus we conclude that <math> \displaystyle AE = DE </math> if and only if <math> \displaystyle \alpha + \beta = \pi/3 </math>, Q.E.D.
+From these inequalities, we see that <math>\sin (\pi - 2\alpha - \beta ) = \sin (\pi - 2\beta - \alpha) </math> if and only if <math>(\pi - 2\alpha - \beta) = (\pi - 2\beta - \alpha) </math> (i.e., <math>\alpha = \beta </math>) or <math>(\pi - 2\alpha - \beta) + (\pi - 2\beta - \alpha) = \pi </math> (i.e., <math>3(\alpha + \beta) = \pi </math>).  But if <math>\alpha = \beta </math>, then triangles <math>ABC, BCD </math> are congruent and <math>AC = BD </math>, a contradiction.  Thus we conclude that <math>AE = DE </math> if and only if <math>\alpha + \beta = \pi/3 </math>, Q.E.D.

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Difference between revisions of "2007 BMO Problems/Problem 1"

Revision as of 23:41, 23 October 2012

Problem

Solution

Resources