Difference between revisions of "1964 IMO Problems/Problem 3"

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[BHM]/[BCA] = (perimeter of BHM/perimeter of BCA)^2 ={(2s-2b)/(a+b+c)}^2 ={(c+a-b)/(c+a+b)}^2
 
[BHM]/[BCA] = (perimeter of BHM/perimeter of BCA)^2 ={(2s-2b)/(a+b+c)}^2 ={(c+a-b)/(c+a+b)}^2
 
  Thus, [BHM]+[CGF]+[ADE]=[ABC]/(a+b+c)^2 { ( b+c-a)^2 + (c+a-b)^2 + (a+b-c)^2}
 
  Thus, [BHM]+[CGF]+[ADE]=[ABC]/(a+b+c)^2 { ( b+c-a)^2 + (c+a-b)^2 + (a+b-c)^2}
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Denote <math>[ABC]</math> the area of <math>\triangle ABC</math> and <math>(ABC)</math> the perimeter of <math>\triangle ABC</math>.
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Then <math>\frac{[BHM]}{[ABC]} = \left(\frac{(BHM)}{(ABC)}\right)^{2} =\left(\frac{c+a-b}{c+a+b}\right)^{2} </math>.
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So <math>[BHM]=\left(\frac{c+a-b}{c+a+b}\right)^{2}\cdot [ABC]</math>.
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We know, <math>r_{1}</math> is the radius of the incircle of <math>\triangle BHM</math>: <math> r_{1}= 2 \cdot \frac{[BHM]}{(BHM)}</math>.
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Area of the incircle of <math>\triangle BHM</math>
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<cmath>= \pi \cdot 4 \cdot (\frac{[BHM]}{(BHM)})^{2}= 4\pi \frac{(c+a-b)^{2}}{(c+a+b)^{4}} \cdot ([ABC])^{2}</cmath>
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Area of the incircle of <math>\triangle ABC</math>:<math>4\pi (\frac{[ABC]}{a+b+c})^{2}</math>.
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Sum of the area of the 4 incircles:
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<cmath>4 \pi ([ABC])^{2}\left[\frac{(c+a-b)^{2}+(b+c-a)^{2}+(c+a-b)^{2}}{(a+b+c)^{4}}\right]+4\pi (\frac{[ABC]}{a+b+c})^{2}</cmath>
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<cmath>=4 \pi \frac{([ABC])^{2}}{(a+b+c)^{2}}\left[\frac{(c+a-b)^{2}+(b+c-a)^{2}+(c+a-b)^{2}+(a+b+c)^{2}}{(a+b+c)^{2}}\right]</cmath>
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<cmath>=16 \pi \frac{([ABC])^{2}(a^{2}+b^{2}+c^{2})}{(a+b+c)^{4}}</cmath>

Revision as of 15:32, 17 December 2012

Problem

A circle is inscribed in a triangle $ABC$ with sides $a,b,c$. Tangents to the circle parallel to the sides of the triangle are contructed. Each of these tangents cuts off a triangle from $\triangle ABC$. In each of these triangles, a circle is inscribed. Find the sum of the areas of all four inscribed circles (in terms of $a,b,c$).

Solution

This problem needs a solution. If you have a solution for it, please help us out by adding it. Let the tangent to the in circle parallel to BC cut AB,AC at D & E respectively. Similarly let the tangent to the same parallel to AB cut AC,BC at F & G respectively and the tangent to the same parallel to AC cuts BC,AB at H,M respectively. Let the incircle touch the sides BC,CA,AB at P,Q,R respectively and let the points of contact of MH,FG,DE with the in circle be X,Y,Z respectively. Then perimeter of BHM = BH+HX+XM+MB=BH+HP+MR+BM=BP+BQ=2(s-b) and similar results follow!

Each of the triangles BHM,CGF,ADE are similar to ABC. 

[BHM]/[BCA] = (perimeter of BHM/perimeter of BCA)^2 ={(2s-2b)/(a+b+c)}^2 ={(c+a-b)/(c+a+b)}^2

Thus, [BHM]+[CGF]+[ADE]=[ABC]/(a+b+c)^2 { ( b+c-a)^2 + (c+a-b)^2 + (a+b-c)^2}


Denote $[ABC]$ the area of $\triangle ABC$ and $(ABC)$ the perimeter of $\triangle ABC$.

Then $\frac{[BHM]}{[ABC]} = \left(\frac{(BHM)}{(ABC)}\right)^{2} =\left(\frac{c+a-b}{c+a+b}\right)^{2}$.

So $[BHM]=\left(\frac{c+a-b}{c+a+b}\right)^{2}\cdot [ABC]$.

We know, $r_{1}$ is the radius of the incircle of $\triangle BHM$: $r_{1}= 2 \cdot \frac{[BHM]}{(BHM)}$.

Area of the incircle of $\triangle BHM$ \[= \pi \cdot 4 \cdot (\frac{[BHM]}{(BHM)})^{2}= 4\pi \frac{(c+a-b)^{2}}{(c+a+b)^{4}} \cdot ([ABC])^{2}\] Area of the incircle of $\triangle ABC$:$4\pi (\frac{[ABC]}{a+b+c})^{2}$. Sum of the area of the 4 incircles: \[4 \pi ([ABC])^{2}\left[\frac{(c+a-b)^{2}+(b+c-a)^{2}+(c+a-b)^{2}}{(a+b+c)^{4}}\right]+4\pi (\frac{[ABC]}{a+b+c})^{2}\] \[=4 \pi \frac{([ABC])^{2}}{(a+b+c)^{2}}\left[\frac{(c+a-b)^{2}+(b+c-a)^{2}+(c+a-b)^{2}+(a+b+c)^{2}}{(a+b+c)^{2}}\right]\] \[=16 \pi \frac{([ABC])^{2}(a^{2}+b^{2}+c^{2})}{(a+b+c)^{4}}\]