Difference between revisions of "1981 IMO Problems/Problem 5"

m
 
(4 intermediate revisions by 4 users not shown)
Line 1: Line 1:
 
== Problem ==
 
== Problem ==
  
Three [[congruent]] [[circle]]s have a common point <math> \displaystyle O </math> and lie inside a given [[triangle]]. Each circle touches a pair of sides of the triangle. Prove that the [[incenter]] and the [[circumcenter]] of the triangle and the point <math>\displaystyle O </math> are [[collinear]].
+
Three [[congruent]] [[circle]]s have a common point <math>O</math> and lie inside a given [[triangle]]. Each circle touches a pair of sides of the triangle. Prove that the [[incenter]] and the [[circumcenter]] of the triangle and the point <math>O </math> are [[collinear]].
  
== Solution ==
+
== Solution 1==
  
Let the triangle have vertices <math>\displaystyle A,B,C</math>, and sides <math>\displaystyle a,b,c</math>, respectively, and let the centers of the circles inscribed in the [[angle]]s <math>\displaystyle A,B,C</math> be denoted <math>\displaystyle O_A, O_B, O_C </math>, respectively.
+
Let the triangle have vertices <math>A,B,C</math>, and sides <math>a,b,c</math>, respectively, and let the centers of the circles inscribed in the [[angle]]s <math>A,B,C</math> be denoted <math>O_A, O_B, O_C </math>, respectively.
  
The triangles <math> \displaystyle O_A O_B O_C </math> and <math> \displaystyle ABC </math> are [[homothetic]], as their corresponding sides are [[parallel]].  Furthermore, since <math>\displaystyle O_A</math> lies on the [[angle bisector | bisector]] of angle <math>\displaystyle A</math> and similar relations hold for the triangles' other corresponding points, the center of homothety is the incenter of both the triangles.  Since <math>\displaystyle O</math> is clearly the circumcenter of <math>\displaystyle O_A O_B O_C </math>, <math>\displaystyle O</math> is collinear with the incenter and circumcenter of <math>\displaystyle ABC</math>, as desired.
+
The triangles <math>O_A O_B O_C </math> and <math>ABC </math> are [[homothetic]], as their corresponding sides are [[parallel]].  Furthermore, since <math>O_A</math> lies on the [[angle bisector | bisector]] of angle <math>A</math> and similar relations hold for the triangles' other corresponding points, the center of homothety is the incenter of both the triangles.  Since <math>O</math> is clearly the circumcenter of <math>O_A O_B O_C </math>, <math>O</math> is collinear with the incenter and circumcenter of <math>ABC</math>, as desired.
  
{{alternate solutions}}
+
==Solution 2==
 +
----
 +
Suppose 3 congruent circles with centres P,Q,R lie inside ABC and are such that the circle with centre P touches AB & AC and the circle with centre Q touches CA & BC.an R with remaining 2.
 +
----
 +
Since O lies in all 3 circles, PO=QO=RO. Therefore, O is circumcentre of PQR. let O' be circumcentre of ABC.
 +
----
 +
Since BC is tangent to the circles with centers Q & R, the lengths of perpendiculars from Q & R, the lengths are equal. therefore,  QR//BC,RP//CA,PQ//AB.
 +
----
 +
Again, since AB and AC both touch circle with centre P. Therefore P is equidistant from AB & AC. Therefore P lies on the internal bisector of angle A. Similarly Q & R lie internal bisectors of angle B and angle C respectively. Therefore, AP,BQ,CR produced meet at incenter I. Since, QR//BC,RP//CA,PQ//AB, it follows that I is also incentre of PQR, I being the centre of homothety. By the property of enlargements, O and O' must be co-linear with I , the centre of enlargement.
  
== Resources ==
+
== See Also == {{IMO box|year=1981|num-b=4|num-a=6}}
 
 
* [[1981 IMO Problems]]
 
* [http://www.artofproblemsolving.com/Forum/viewtopic.php?p=366643#p366643 Discussion on AoPS/MathLinks]
 
 
 
 
 
[[Category:Olympiad Geometry Problems]]
 

Latest revision as of 22:09, 29 January 2021

Problem

Three congruent circles have a common point $O$ and lie inside a given triangle. Each circle touches a pair of sides of the triangle. Prove that the incenter and the circumcenter of the triangle and the point $O$ are collinear.

Solution 1

Let the triangle have vertices $A,B,C$, and sides $a,b,c$, respectively, and let the centers of the circles inscribed in the angles $A,B,C$ be denoted $O_A, O_B, O_C$, respectively.

The triangles $O_A O_B O_C$ and $ABC$ are homothetic, as their corresponding sides are parallel. Furthermore, since $O_A$ lies on the bisector of angle $A$ and similar relations hold for the triangles' other corresponding points, the center of homothety is the incenter of both the triangles. Since $O$ is clearly the circumcenter of $O_A O_B O_C$, $O$ is collinear with the incenter and circumcenter of $ABC$, as desired.

Solution 2


Suppose 3 congruent circles with centres P,Q,R lie inside ABC and are such that the circle with centre P touches AB & AC and the circle with centre Q touches CA & BC.an R with remaining 2.


Since O lies in all 3 circles, PO=QO=RO. Therefore, O is circumcentre of PQR. let O' be circumcentre of ABC.


Since BC is tangent to the circles with centers Q & R, the lengths of perpendiculars from Q & R, the lengths are equal. therefore, QR//BC,RP//CA,PQ//AB.


Again, since AB and AC both touch circle with centre P. Therefore P is equidistant from AB & AC. Therefore P lies on the internal bisector of angle A. Similarly Q & R lie internal bisectors of angle B and angle C respectively. Therefore, AP,BQ,CR produced meet at incenter I. Since, QR//BC,RP//CA,PQ//AB, it follows that I is also incentre of PQR, I being the centre of homothety. By the property of enlargements, O and O' must be co-linear with I , the centre of enlargement.

See Also

1981 IMO (Problems) • Resources
Preceded by
Problem 4
1 2 3 4 5 6 Followed by
Problem 6
All IMO Problems and Solutions