Difference between revisions of "2007 IMO Problems/Problem 4"

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In <math>\triangle ABC</math> the bisector of <math>\angle{BCA}</math> intersects the circumcircle again at <math>R</math>, the perpendicular bisector of <math>BC</math> at <math>P</math>, and the perpendicular bisector of <math>AC</math> at <math>Q</math>. The midpoint of <math>BC</math> is <math>K</math> and the midpoint of <math>AC</math> is <math>L</math>. Prove that the triangles <math>RPK</math> and <math>RQL</math> have the same area.
 
In <math>\triangle ABC</math> the bisector of <math>\angle{BCA}</math> intersects the circumcircle again at <math>R</math>, the perpendicular bisector of <math>BC</math> at <math>P</math>, and the perpendicular bisector of <math>AC</math> at <math>Q</math>. The midpoint of <math>BC</math> is <math>K</math> and the midpoint of <math>AC</math> is <math>L</math>. Prove that the triangles <math>RPK</math> and <math>RQL</math> have the same area.
  
 +
== Diagram ==
  
  
==Solution 1 (Efficient)== From a diagram, we have <math>\angle{RQL}=90+\angle{QCL}=90+\dfrac{C}{2}</math>, and similarly <math>\angle{RPK}=90+\angle{PCK}=90+\dfrac{C}{2}</math>. Therefore, we have <math>\angle{RQL}=\angle{RPK}</math>. Using the trig area of a triangle formula <math>A=\dfrac{1}{2}bc\sin{\angle{A}}</math>, this means we have to prove that <math>RQ \cdot QL=RP \cdot PK</math>, or <math>\dfrac{PK}{QL}=\dfrac{RQ}{RP}</math>. Draw line <math>QD</math> perpendicular to BC that intersects BC at <math>D</math>. Then <math>QD=QL</math> because the perpendicular bisectors are congruent, (or alternatively that <math>\triangle QDC \cong \triangle QLC</math>) <math>\dfrac{PK}{QL}=\dfrac{PC}{QC}=\dfrac{PK}{QD}</math> by similar triangles. Now the problem is to prove <math>\dfrac{PC}{QC}=\dfrac{RQ}{RP}</math>, or <math>RQ \cdot QC=RP \cdot PC</math>. Since <math>\angle{OPQ}=180-\angle{RPK}=180-\angle{RQL}=\angle{OQP}</math>, we have <math>\triangle OPQ</math> is isosceles . Draw the perpendicular from <math>O</math> to <math>RC</math>, intersecting at <math>E</math>. Then <math>PE = QE = x</math> for a real <math>x</math>. Now, because the perpendicular from the center of a circle to a chord bisects that chord, <math>RE = CE</math>. Let <math>y = RE</math>. Then <math>RQ \cdot QC = (y+x) \cdot (y-x) = PC \cdot RP</math>, proving our claim. <math>\boxed{QED}</math>
 
  
=Alternative Solution (Power of a Point)= From <math>\angle{OPQ}=180-\angle{RPK}=180-\angle{RQL}=\angle{OQP}</math>, we have <math>OQ=OP=x</math>. Let the radius of the circumcircle be <math>r</math>, then the diameter through <math>P</math> is divided by point <math>P</math> into lengths of <math>r+x</math> and <math>r-x</math>. By power of point,  <math>RP*PC=(r+x)(r-x)</math>. Similarly, <math>RQ*QC=(r+x)(r-x)</math>. Therefore <math>RP*PC=RQ*QC</math>. <math>\square</math>  
+
<asy>
 +
size(300);
 +
import olympiad;
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real c=8.1,a=5*(c+sqrt(c^2-64))/6,b=5*(c-sqrt(c^2-64))/6;
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pair A=(0,0),B=(c,0),R=(c/2,-sqrt(25-(c/2)^2));
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pair C=intersectionpoints(circle(A,b),circle(B,a))[0];
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pair K = midpoint(B--C);
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pair L = midpoint(A--C);
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pair I=incenter(A,B,C);
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pair O = circumcenter(A,B,C);
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dot(O);
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dot(A^^B^^C^^R^^K^^L);
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draw(C--R);
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draw(circumcircle(A,B,R));
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draw(A--C--B);
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draw(A--B);
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label("$A$",A,SW);
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label("$B$",B,SE);
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label("$C$",C,N);
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label("$R$",R,S);
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label("$K$",K,N);
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label("$L$",L,S);
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label("$O$",O,N);
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draw(K--O);
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draw(L--O);
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pair Q = intersectionpoint(L--O, C--R);
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dot(Q);
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label("$Q$",Q,SW);
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pair E = midpoint(C--R);
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dot(E);
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label("$E$",E,W);
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draw(O--E, dashed);
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pair P = intersectionpoint(O--(c/2-1.2,0), C--R);
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dot(P);
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label("$P$",P,W);
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draw(O--P);
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draw(R--L, dashed);
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draw(R--K, dashed);
 +
 
 +
 
 +
 
 +
</asy>
 +
 
 +
~KingRavi
 +
 
 +
== Solution 1 (Efficient) ==
 +
 
 +
<math>\angle{RQL} = 90+\angle{QCL} = 90+\dfrac{C}{2}</math>, and similarly <math>\angle{RPK} = 90+\angle{PCK} = 90+\dfrac{C}{2}</math>. Therefore, <math>\angle{RQL} = \angle{RPK}</math>. Using the triangle area formula <math>A = \dfrac{1}{2}bc\sin{\angle{A}}</math> yields <math>RQ \cdot QL = RP \cdot PK = \dfrac{PK}{QL} = \dfrac{RQ}{RP}</math> after cancelling the sines and constant. Draw line <math>QD</math> perpendicular to <math>BC</math> that intersects <math>BC</math> at <math>D</math>, then <math>QD=QL</math> because the perpendicular bisectors are congruent, (or alternatively <math>\triangle QDC\cong\triangle QLC</math>). This presents us <math>\dfrac{PK}{QL}=\dfrac{PK}{QD}=\dfrac{PC}{QC}</math> by similar triangles; now, we have only to prove <math>\dfrac{PC}{QC}=\dfrac{RQ}{RP}</math>, or <math>RQ \cdot QC=RP \cdot PC</math>.
 +
 
 +
Since <math>\angle{OPQ} =1 80-\angle{RPK} =1 80-\angle{RQL} = \angle{OQP}</math>, we have <math>\triangle OPQ</math> is isosceles. Draw the perpendicular from <math>O</math> to <math>RC</math>, intersecting at <math>E</math>. Then <math>PE = QE = x</math> for a real <math>x</math>, now because the perpendicular from the center of a circle to a chord bisects that chord, <math>RE = CE</math>. Let <math>y = RE</math>, and then <math>RQ \cdot QC = (y+x) \cdot (y-x) = PC \cdot RP</math>, proving our claim.
 +
 
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== Alternative END Solution (Power of a Point) ==
 +
 +
Since <math>\angle{OPQ}=180-\angle{RPK}=180-\angle{RQL}=\angle{OQP}</math>, we have <math>OQ=OP=x</math>. Let the radius of the circumcircle be <math>r</math>, then the diameter through <math>P</math> is divided by point <math>P</math> into lengths of <math>r+x</math> and <math>r-x</math>. By power of point,  <math>RP*PC=(r+x)(r-x)</math>. Similarly, <math>RQ*QC=(r+x)(r-x)</math>. Therefore <math>RP*PC=RQ*QC</math>. <math>\square</math>  
  
 
Solution by ~KingRavi
 
Solution by ~KingRavi
  
 
Alternate Solution by ~mathdummy
 
Alternate Solution by ~mathdummy
 +
 +
Edifying edits made by ~TheGrandioseGeometrician
  
 
==Solution 2==
 
==Solution 2==
Line 42: Line 97:
 
<cmath>= \dfrac{\frac{1}{2}a\tan\frac{1}{2}C \cdot (a + b)}{a\sin\frac{1}{2}C}  </cmath>
 
<cmath>= \dfrac{\frac{1}{2}a\tan\frac{1}{2}C \cdot (a + b)}{a\sin\frac{1}{2}C}  </cmath>
 
<cmath>= \dfrac{\frac{1}{2}a\sin\frac{1}{2}C \cdot (a + b)}{a\sin\frac{1}{2}C\cos\frac{1}{2}C} </cmath>
 
<cmath>= \dfrac{\frac{1}{2}a\sin\frac{1}{2}C \cdot (a + b)}{a\sin\frac{1}{2}C\cos\frac{1}{2}C} </cmath>
<cmath>= \dfrac{\frac{1}{2}C \cdot (a + b)}{2\sin \frac{1}{2}C\cos\frac{1}{2}C}          </cmath>
+
<cmath>= \dfrac{\sin\frac{1}{2}C \cdot (a + b)}{2\sin \frac{1}{2}C\cos\frac{1}{2}C}          </cmath>
<cmath>= \dfrac{\frac{1}{2}C \cdot (a + b)}{\sin C}          </cmath>
+
<cmath>= \dfrac{\sin\frac{1}{2}C \cdot (a + b)}{\sin C}          </cmath>
<cmath>= \dfrac{\frac{1}{2}C \cdot (a + b)}{c}          </cmath>
+
<cmath>= \dfrac{\sin\frac{1}{2}C \cdot (a + b)}{c}          </cmath>
 
<cmath>= CR. </cmath>
 
<cmath>= CR. </cmath>
 
Thus, <math>RF = \dfrac{1}{2}b.</math> In this way, we get that the altidude from <math>R</math> to <math>QL</math> has length <math>\dfrac{1}{2}a.</math> Therefore, we see that <math>[RPK] = \dfrac{1}{8}ab \tan \frac{1}{2}C</math> and <math>[RQL] = \dfrac{1}{8}ab \tan \frac{1}{2}C,</math> so the two areas are equal.  
 
Thus, <math>RF = \dfrac{1}{2}b.</math> In this way, we get that the altidude from <math>R</math> to <math>QL</math> has length <math>\dfrac{1}{2}a.</math> Therefore, we see that <math>[RPK] = \dfrac{1}{8}ab \tan \frac{1}{2}C</math> and <math>[RQL] = \dfrac{1}{8}ab \tan \frac{1}{2}C,</math> so the two areas are equal.  
  
Solution by Ilikeapos  
+
Solution by Ilikeapos
 +
 
 +
==Solution 4==
 +
 
 +
<math>[\triangle{RPK}]=[\triangle{RQL}], LQ*RQ*\sin\angle{LQR}=KP*PR*\sin\angle{RPK}</math>
 +
 
 +
Since <math>CR</math> bisects <math>\angle{ACB},\angle{QCL}=\angle{PCK}</math>, <math>OL,OK</math> are perpendicular to sides <math>AC,BC</math> separately, <math>\angle{QLC}=\angle{PKC}=90^{\circ}, \angle{CQL}=\angle{CPK}, \angle{LQR}=\angle{RPK}</math>
 +
 
 +
So now, we only have to prove <math>RP*PK=LQ*QR</math>, which is <math>RP*(CQ+QP)*\cos\angle{CPK}=CQ*(QP+PR)*\cos\angle{CQL}</math>, as mentioned above, the two angles are the same, we have to prove that <math>RP(CQ+QP)=CQ(QP+PR)</math>, which is equivalent to <math>RP*QP=QP*CQ</math>, we have to prove <math>RP=CQ</math>
 +
 
 +
Now notice that <math>\triangle{OQP}</math> is isosceles. <math>\angle{CQL}=\angle{OQP}=\angle{OPQ}</math>, construct <math>OJ \bot CR</math>, <math>CJ=JR,JQ=JP,CQ=PR</math> as desired
 +
 
 +
~bluesoul
  
 
{{alternate solutions}}
 
{{alternate solutions}}

Latest revision as of 13:52, 5 August 2022

Problem

In $\triangle ABC$ the bisector of $\angle{BCA}$ intersects the circumcircle again at $R$, the perpendicular bisector of $BC$ at $P$, and the perpendicular bisector of $AC$ at $Q$. The midpoint of $BC$ is $K$ and the midpoint of $AC$ is $L$. Prove that the triangles $RPK$ and $RQL$ have the same area.

Diagram

[asy] size(300); import olympiad; real c=8.1,a=5*(c+sqrt(c^2-64))/6,b=5*(c-sqrt(c^2-64))/6; pair A=(0,0),B=(c,0),R=(c/2,-sqrt(25-(c/2)^2)); pair C=intersectionpoints(circle(A,b),circle(B,a))[0]; pair K = midpoint(B--C); pair L = midpoint(A--C); pair I=incenter(A,B,C); pair O = circumcenter(A,B,C); dot(O); dot(A^^B^^C^^R^^K^^L); draw(C--R); draw(circumcircle(A,B,R)); draw(A--C--B); draw(A--B); label("$A$",A,SW); label("$B$",B,SE); label("$C$",C,N); label("$R$",R,S); label("$K$",K,N); label("$L$",L,S); label("$O$",O,N); draw(K--O); draw(L--O); pair Q = intersectionpoint(L--O, C--R); dot(Q); label("$Q$",Q,SW); pair E = midpoint(C--R); dot(E); label("$E$",E,W); draw(O--E, dashed); pair P = intersectionpoint(O--(c/2-1.2,0), C--R); dot(P); label("$P$",P,W); draw(O--P); draw(R--L, dashed); draw(R--K, dashed);    [/asy]

~KingRavi

Solution 1 (Efficient)

$\angle{RQL} = 90+\angle{QCL} = 90+\dfrac{C}{2}$, and similarly $\angle{RPK} = 90+\angle{PCK} = 90+\dfrac{C}{2}$. Therefore, $\angle{RQL} = \angle{RPK}$. Using the triangle area formula $A = \dfrac{1}{2}bc\sin{\angle{A}}$ yields $RQ \cdot QL = RP \cdot PK = \dfrac{PK}{QL} = \dfrac{RQ}{RP}$ after cancelling the sines and constant. Draw line $QD$ perpendicular to $BC$ that intersects $BC$ at $D$, then $QD=QL$ because the perpendicular bisectors are congruent, (or alternatively $\triangle QDC\cong\triangle QLC$). This presents us $\dfrac{PK}{QL}=\dfrac{PK}{QD}=\dfrac{PC}{QC}$ by similar triangles; now, we have only to prove $\dfrac{PC}{QC}=\dfrac{RQ}{RP}$, or $RQ \cdot QC=RP \cdot PC$.

Since $\angle{OPQ} =1 80-\angle{RPK} =1 80-\angle{RQL} = \angle{OQP}$, we have $\triangle OPQ$ is isosceles. Draw the perpendicular from $O$ to $RC$, intersecting at $E$. Then $PE = QE = x$ for a real $x$, now because the perpendicular from the center of a circle to a chord bisects that chord, $RE = CE$. Let $y = RE$, and then $RQ \cdot QC = (y+x) \cdot (y-x) = PC \cdot RP$, proving our claim.

Alternative END Solution (Power of a Point)

Since $\angle{OPQ}=180-\angle{RPK}=180-\angle{RQL}=\angle{OQP}$, we have $OQ=OP=x$. Let the radius of the circumcircle be $r$, then the diameter through $P$ is divided by point $P$ into lengths of $r+x$ and $r-x$. By power of point, $RP*PC=(r+x)(r-x)$. Similarly, $RQ*QC=(r+x)(r-x)$. Therefore $RP*PC=RQ*QC$. $\square$

Solution by ~KingRavi

Alternate Solution by ~mathdummy

Edifying edits made by ~TheGrandioseGeometrician

Solution 2

The area of $\triangle{RQL}$ is given by $\dfrac{1}{2}QL*RQ\sin{\angle{RQL}}$ and the area of $\triangle{RPK}$ is $\dfrac{1}{2}RP*PK\sin{\angle{RPK}}$. Let $\angle{BCA}=C$, $\angle{BAC}=A$, and $\angle{ABC}=B$. Now $\angle{KCP}=\angle{QCL}=\dfrac{C}{2}$ and $\angle{PKC}=\angle{QLC}=90$, thus $\angle{RPK}=\angle{RQL}=90+\dfrac{C}{2}$. $\triangle{PKC} \sim \triangle{QLC}$, so $\dfrac{PK}{QL}=\dfrac{KC}{LC}$, or $\dfrac{PK}{QL}=\dfrac{BC}{AB}$. The ratio of the areas is $\dfrac{[RPK]}{[RQL]}=\dfrac{BC*RP}{AC*RQ}$. The two areas are only equal when the ratio is 1, therefore it suffices to show $\dfrac{RP}{RQ}=\dfrac{AC}{BC}$. Let $O$ be the center of the circle. Then $\angle{ROK}=A+C$, and $\angle{ROP}=180-(A+C)=B$. Using law of sines on $\triangle{RPO}$ we have: $\dfrac{RP}{\sin{B}}=\dfrac{OR}{\sin{(90+\dfrac{C}{2})}}$ so $RP*\sin{(90+\dfrac{C}{2})}=OR*\sin{B}$. $OR*\sin{B}=\dfrac{1}{2}AC$ by law of sines, and $\sin{(90+\dfrac{C}{2})}=\cos{\dfrac{C}{2}}$, thus 1) $2RP\cos{\dfrac{C}{2}}=AC$. Similarly, law of sines on $\triangle{ROQ}$ results in $\dfrac{RQ}{\sin{(180-A)}}=\dfrac{OR}{\sin{(90-\dfrac{C}{2})}}$ or $\dfrac{RQ}{\sin{A}}=\dfrac{OR}{\cos{\dfrac{C}{2}}}$. Cross multiplying we have $RQ\cos{\dfrac{C}{2}}=OR*\sin{A}$ or 2) $2RQ\cos{\dfrac{C}{2}}=BC$. Dividing 1) by 2) we have $\dfrac{RP}{RQ}=\dfrac{AC}{BC}$ $\square$

$(tkhalid)$

Solution 3

(Image Link) https://services.artofproblemsolving.com/download.php?id=YXR0YWNobWVudHMvYi85LzQ5OTJlZGNhYTQ0YjJjODcxMTBmZGNmMTdiZDdkMGRjZGUyOWQ5LnBuZw==&rn=U2NyZWVuIFNob3QgMjAxOS0wOC0wOCBhdCAxMi4yMC4zOCBQTS5wbmc=

WLOG, let the diameter of $(ACBR)$ be $1.$

We see that $PK = \dfrac{1}{2}a \tan \dfrac{1}{2}C$ and $QL = \dfrac{1}{2}b \tan \dfrac{1}{2}C$ from right triangles $\triangle PKC$ and $\triangle QLC.$

We now look at $AR.$ By the Extended Law of Sines on $\triangle ACR,$ we get that $AR = \sin\frac{1}{2}C.$ Similarly, $BR = \sin \frac{1}{2}C.$

We now look at $CR.$ By Ptolemy's Theorem, we have \[AR \cdot BC + BR \cdot AC = AB \cdot CR,\] which gives us \[\sin \frac{1}{2}C (a + b) = c(CR).\] This means that \[CR = \dfrac{\sin \frac{1}{2}C (a + b)}{c}.\] We now seek to relate the lengths computed with the areas.

To do this, we consider the altitude from $R$ to $PK.$ This is to find the area of $RPK.$ Finding the area of $\triangle RQL$ is similar.

We claim that $RF = \dfrac{1}{2}b.$ In order to prove this, we will prove that $\triangle RFP \cong \triangle QLC.$ In other words, we wish to prove that $PR = QC.$ This is equivalent to proving that $PC + QC = CR.$

Note that $PC = \dfrac{PK}{\sin \frac{1}{2}C}$ and $QC = \dfrac{QL}{\sin \frac{1}{2}C}.$ Therefore, we get that \[PC + QC = \dfrac{PK}{\sin \frac{1}{2}C} + \dfrac{QL}{\sin\frac{1}{2}C}\] \[= \dfrac{PK + QL}{\sin\frac{1}{2}C}\] \[= \dfrac{PK(1 + \frac{b}{a})}{\sin\frac{1}{2}C}\] \[= \dfrac{PK(\frac{a + b}{a})}{\sin\frac{1}{2}C}\] \[= \dfrac{\frac{1}{2}a\tan\frac{1}{2}C \cdot (a + b)}{a\sin\frac{1}{2}C}\] \[= \dfrac{\frac{1}{2}a\sin\frac{1}{2}C \cdot (a + b)}{a\sin\frac{1}{2}C\cos\frac{1}{2}C}\] \[= \dfrac{\sin\frac{1}{2}C \cdot (a + b)}{2\sin \frac{1}{2}C\cos\frac{1}{2}C}\] \[= \dfrac{\sin\frac{1}{2}C \cdot (a + b)}{\sin C}\] \[= \dfrac{\sin\frac{1}{2}C \cdot (a + b)}{c}\] \[= CR.\] Thus, $RF = \dfrac{1}{2}b.$ In this way, we get that the altidude from $R$ to $QL$ has length $\dfrac{1}{2}a.$ Therefore, we see that $[RPK] = \dfrac{1}{8}ab \tan \frac{1}{2}C$ and $[RQL] = \dfrac{1}{8}ab \tan \frac{1}{2}C,$ so the two areas are equal.

Solution by Ilikeapos

Solution 4

$[\triangle{RPK}]=[\triangle{RQL}], LQ*RQ*\sin\angle{LQR}=KP*PR*\sin\angle{RPK}$

Since $CR$ bisects $\angle{ACB},\angle{QCL}=\angle{PCK}$, $OL,OK$ are perpendicular to sides $AC,BC$ separately, $\angle{QLC}=\angle{PKC}=90^{\circ}, \angle{CQL}=\angle{CPK}, \angle{LQR}=\angle{RPK}$

So now, we only have to prove $RP*PK=LQ*QR$, which is $RP*(CQ+QP)*\cos\angle{CPK}=CQ*(QP+PR)*\cos\angle{CQL}$, as mentioned above, the two angles are the same, we have to prove that $RP(CQ+QP)=CQ(QP+PR)$, which is equivalent to $RP*QP=QP*CQ$, we have to prove $RP=CQ$

Now notice that $\triangle{OQP}$ is isosceles. $\angle{CQL}=\angle{OQP}=\angle{OPQ}$, construct $OJ \bot CR$, $CJ=JR,JQ=JP,CQ=PR$ as desired

~bluesoul

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

2007 IMO (Problems) • Resources
Preceded by
Problem 3
1 2 3 4 5 6 Followed by
Problem 5
All IMO Problems and Solutions