1988 IMO Problems/Problem 5: Difference between revisions

Latest revision as of 10:38, 30 January 2021

Problem

In a right-angled triangle $ABC$ let $AD$ be the altitude drawn to the hypotenuse and let the straight line joining the incentres of the triangles $ABD, ACD$ intersect the sides $AB, AC$ at the points $K,L$ respectively. If $E$ and $E_1$ dnote the areas of triangles $ABC$ and $AKL$ respectively, show that $\frac {E}{E_1} \geq 2.$

Solution

Lemma: Through the incenter $I$ of $\triangle{ABC}$ draw a line that meets the sides $AB$ and $AC$ at $P$ and $Q$ , then: $\frac{AB}{AP} \cdot AC + \frac{AC}{AQ} \cdot AB = AB+BC+AC$ Proof of the lemma: Consider the general case: $M$ is any point on side $BC$ and $PQ$ is a line cutting AB, AM, AC at P, N, Q. Then:

$\frac{AM}{AN}=\frac{S_{APMQ}}{\triangle{APQ}}=\frac{\triangle{APM}+\triangle{AQM}}{\triangle{PQA}}=\frac{\frac{AP}{AB}\triangle{ABM}+\frac{AQ}{AC}\triangle{ACM}}{\frac{AP\cdot AQ}{AB \cdot AC}}=$

$=\frac{AC}{AQ}\cdot \frac{BM}{BC}+\frac{AB}{AP}\cdot \frac{CM}{BC}$

If $N$ is the incentre then $\frac{AM}{AN}=\frac{AB+BC+CA}{AB+AC}$ , $\frac{BM}{BC}=\frac{AB}{AB+AC}$ and $\frac{CM}{BC}=\frac{AC}{AC+AB}$ . Plug them in we get: $\frac{AB}{AP} \cdot AC + \frac{AC}{AQ} \cdot AB = AB+BC+AC$

Back to the problem Let $I_1$ and $I_2$ be the areas of $\triangle{ABD}$ and $\triangle{ACD}$ and $E$ be the intersection of $KL$ and $AD$ . Thus apply our formula in the two triangles we get: $\frac{AD}{AE} \cdot AB + \frac{AB}{AK} \cdot AD = AB+BD+AD$ and $\frac{AD}{AE} \cdot AC + \frac{AC}{AL} \cdot AD = AC+CD+AD$ Cancel out the term $\frac{AD}{AE}$ , we get: $\frac{AB+BD+AD-\frac{AB}{AK} \cdot AD }{AC+CD+AD- \frac{AC}{AL} \cdot AD }=\frac{AB}{AC}$ $AB \cdot CD + AB \cdot AD - \frac{AB \cdot AC \cdot AD}{AL}=AC \cdot BD+ AC \cdot AD -\frac{AB \cdot AC \cdot AD}{AK}$ $AB+AB \cdot \frac{CD}{AD}-\frac{AB \cdot AC}{AL}=AC+ AC \cdot \frac{BD}{AD} - \frac{AB \cdot AC}{AK}$ $AB+AC - \frac{AB \cdot AC}{AL}=AB+AC - \frac{AB \cdot AC}{AK}$ $\frac{AB \cdot AC}{AK} = \frac{AB \cdot AC}{AL}$ So we conclude $AK=AL$ .

Hence $\angle{AKI_1}=45^o=\angle{ADI_1}$ and $\angle{ALI_2}=45^o=\angle{ADI_2}$ , thus $\triangle{AK_1} \cong \triangle{ADI_1}$ and $\triangle{ALI_2} \cong \triangle{ADI_2}$ . Thus $AK=AD=AL$ . So the area ratio is: $\frac{E}{E_1}=\frac{AB \cdot AC}{AD^2} = \frac{BC}{AD} =\frac{BD+CD}{\sqrt{BD \cdot CD}}\geq 2$

This solution was posted and copyrighted by shobber. The original thread for this problem can be found here: [1]

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+==Problem==
+In a right-angled triangle <math> ABC</math> let <math> AD</math> be the altitude drawn to the hypotenuse and let the straight line joining the incentres of the triangles <math> ABD, ACD</math> intersect the sides <math> AB, AC</math> at the points <math> K,L</math> respectively. If <math> E</math> and <math> E_1</math> dnote the areas of triangles <math> ABC</math> and <math> AKL</math> respectively, show that
+<cmath> \frac {E}{E_1} \geq 2.</cmath>
+==Solution==
+Lemma: Through the incenter <math>I</math> of <math>\triangle{ABC}</math> draw a line that meets the sides <math>AB</math> and <math>AC</math> at <math>P</math> and <math>Q</math>, then:
+<cmath> \frac{AB}{AP} \cdot AC + \frac{AC}{AQ} \cdot AB = AB+BC+AC </cmath>
+Proof of the lemma:
+Consider the general case: <math>M</math> is any point on side <math>BC</math> and <math>PQ</math> is a line cutting AB, AM, AC at P, N, Q. Then:
+<math>\frac{AM}{AN}=\frac{S_{APMQ}}{\triangle{APQ}}=\frac{\triangle{APM}+\triangle{AQM}}{\triangle{PQA}}=\frac{\frac{AP}{AB}\triangle{ABM}+\frac{AQ}{AC}\triangle{ACM}}{\frac{AP\cdot AQ}{AB \cdot AC}}=</math>
+<math>=\frac{AC}{AQ}\cdot \frac{BM}{BC}+\frac{AB}{AP}\cdot \frac{CM}{BC}</math>
+If <math>N</math> is the incentre then <math>\frac{AM}{AN}=\frac{AB+BC+CA}{AB+AC}</math>, <math>\frac{BM}{BC}=\frac{AB}{AB+AC}</math> and <math>\frac{CM}{BC}=\frac{AC}{AC+AB}</math>. Plug them in we get:
+<cmath> \frac{AB}{AP} \cdot AC + \frac{AC}{AQ} \cdot AB = AB+BC+AC </cmath>
+Back to the problem
+Let <math>I_1</math> and <math>I_2</math> be the areas of <math>\triangle{ABD}</math> and <math>\triangle{ACD}</math> and <math>E</math> be the intersection of <math>KL</math> and <math>AD</math>. Thus apply our formula in the two triangles we get:
+<cmath> \frac{AD}{AE} \cdot AB + \frac{AB}{AK} \cdot AD = AB+BD+AD </cmath>
+and
+<cmath> \frac{AD}{AE} \cdot AC + \frac{AC}{AL} \cdot AD = AC+CD+AD </cmath>
+Cancel out the term <math>\frac{AD}{AE}</math>, we get:
+<cmath> \frac{AB+BD+AD-\frac{AB}{AK} \cdot AD }{AC+CD+AD- \frac{AC}{AL} \cdot AD }=\frac{AB}{AC} </cmath>
+<cmath> AB \cdot CD + AB \cdot AD - \frac{AB \cdot AC \cdot AD}{AL}=AC \cdot BD+ AC \cdot AD -\frac{AB \cdot AC \cdot AD}{AK} </cmath>
+<cmath> AB+AB \cdot \frac{CD}{AD}-\frac{AB \cdot AC}{AL}=AC+ AC \cdot \frac{BD}{AD} - \frac{AB \cdot AC}{AK} </cmath>
+<cmath> AB+AC - \frac{AB \cdot AC}{AL}=AB+AC - \frac{AB \cdot AC}{AK} </cmath>
+<cmath> \frac{AB \cdot AC}{AK} = \frac{AB \cdot AC}{AL} </cmath>
+So we conclude <math>AK=AL</math>.
+Hence <math>\angle{AKI_1}=45^o=\angle{ADI_1}</math> and <math>\angle{ALI_2}=45^o=\angle{ADI_2}</math>, thus <math>\triangle{AK_1} \cong \triangle{ADI_1}</math> and <math>\triangle{ALI_2} \cong \triangle{ADI_2}</math>. Thus <math>AK=AD=AL</math>. So the area ratio is:
+<cmath> \frac{E}{E_1}=\frac{AB \cdot AC}{AD^2} = \frac{BC}{AD} =\frac{BD+CD}{\sqrt{BD \cdot CD}}\geq 2 </cmath>
+This solution was posted and copyrighted by shobber. The original thread for this problem can be found here: [https://aops.com/community/p510257]
+== See Also == {{IMO box|year=1988|num-b=4|num-a=6}}
+[[Category:Olympiad Geometry Problems]]

1988 IMO (Problems) • Resources
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1988 IMO Problems/Problem 5: Difference between revisions

Latest revision as of 10:38, 30 January 2021

Problem

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