Difference between revisions of "2013 IMO Problems/Problem 4"
(→Solution) |
|||
(13 intermediate revisions by 6 users not shown) | |||
Line 1: | Line 1: | ||
==Problem== | ==Problem== | ||
− | Let <math>ABC</math> be an acute triangle with orthocenter <math>H</math>, and let <math>W</math> be a point on the side <math>BC</math>, lying strictly between <math>B</math> and <math>C</math>. The points <math>M</math> and <math>N</math> are the feet of the altitudes from <math>B</math> and <math>C</math>, respectively. Denote by <math>\omega_1</math> is | + | Let <math>ABC</math> be an acute triangle with orthocenter <math>H</math>, and let <math>W</math> be a point on the side <math>BC</math>, lying strictly between <math>B</math> and <math>C</math>. The points <math>M</math> and <math>N</math> are the feet of the altitudes from <math>B</math> and <math>C</math>, respectively. Denote by <math>\omega_1</math> is the circumcircle of <math>BWN</math>, and let <math>X</math> be the point on <math>\omega_1</math> such that <math>WX</math> is a diameter of <math>\omega_1</math>. Analogously, denote by <math>\omega_2</math> the circumcircle of triangle <math>CWM</math>, and let <math>Y</math> be the point such that <math>WY</math> is a diameter of <math>\omega_2</math>. Prove that <math>X, Y</math> and <math>H</math> are collinear. |
==Hint== | ==Hint== | ||
Line 7: | Line 7: | ||
− | ==Solution== | + | ==Solution 1== |
<asy> | <asy> | ||
//Original diagram by suli, August 2014. Feel free to make edits, but please leave this comment in place. | //Original diagram by suli, August 2014. Feel free to make edits, but please leave this comment in place. | ||
Line 25: | Line 25: | ||
//Time to start drawing | //Time to start drawing | ||
dot(A); dot(B); dot(C); dot(W); dot(H); dot(M); dot(L); dot(X); dot(N); dot(Y); dot(T); | dot(A); dot(B); dot(C); dot(W); dot(H); dot(M); dot(L); dot(X); dot(N); dot(Y); dot(T); | ||
+ | dot(circumcenter(N,B,W)); dot(circumcenter(C,M,W)); | ||
draw(p1); draw(p2); | draw(p1); draw(p2); | ||
draw(A--B--C--Y--W--X--B); | draw(A--B--C--Y--W--X--B); | ||
Line 46: | Line 47: | ||
''Lemma 1:'' <math>T</math> is on <math>XY</math>. | ''Lemma 1:'' <math>T</math> is on <math>XY</math>. | ||
− | Proof: We have <math> | + | Proof: We have <math>\angle{XTW} = \angle{YTW} = 90^\circ</math> because they intercept semicircles. Hence, <math>\angle{XTY} = \angle{XTW} + \angle{YTW} = 180^\circ</math>, so <math>XTY</math> is a straight line. |
''Lemma 2:'' <math>T</math> is on <math>AW</math>. | ''Lemma 2:'' <math>T</math> is on <math>AW</math>. | ||
− | Proof: Let the circumcircles of <math>NBW</math> and <math>MWC</math> be <math>\omega_1</math> and <math>\omega_2</math>, respectively, and, as <math>BNMC</math> is cyclic (from congruent <math> | + | Proof: Let the circumcircles of <math>NBW</math> and <math>MWC</math> be <math>\omega_1</math> and <math>\omega_2</math>, respectively, and, as <math>BNMC</math> is cyclic (from congruent <math>\angle{BNC} = \angle{BMC} = 90^\circ</math>), let its circumcircle be <math>\omega_3</math>. Then each pair of circles' radical axises, <math>BN, TW,</math> and <math>MC</math>, must concur at the intersection of <math>BN</math> and <math>MC</math>, which is <math>A</math>. |
''Lemma 3:'' <math>YT</math> is perpendicular to <math>AW</math>. | ''Lemma 3:'' <math>YT</math> is perpendicular to <math>AW</math>. | ||
− | Proof: This is immediate from <math> | + | Proof: This is immediate from <math>\angle{YTW} = 90^\circ</math>. |
− | Let <math>AH</math> meet <math>BC</math> at <math>L</math>, which is also the foot of the altitude to that side. Hence, <math> | + | Let <math>AH</math> meet <math>BC</math> at <math>L</math>, which is also the foot of the altitude to that side. Hence, <math>\angle{ALB} = 90^\circ.</math> |
''Lemma 4:'' Quadrilateral <math>THLW</math> is cyclic. | ''Lemma 4:'' Quadrilateral <math>THLW</math> is cyclic. | ||
− | Proof: We know that <math>NHLB</math> is cyclic because <math> | + | Proof: We know that <math>NHLB</math> is cyclic because <math>\angle{BNH}</math> and <math>\angle{BLH}</math>, opposite and right angles, sum to <math>180^\circ</math>. Furthermore, we are given that <math>NTWB</math> is cyclic. Hence, by Power of a Point, |
<cmath>AT * AW = AN * AB = AH * AL.</cmath> | <cmath>AT * AW = AN * AB = AH * AL.</cmath> | ||
Line 66: | Line 67: | ||
The converse of Power of a Point then proves <math>THLW</math> cyclic. | The converse of Power of a Point then proves <math>THLW</math> cyclic. | ||
− | Hence, <math> | + | Hence, <math>\angle{WTH} = 180^\circ - \angle{WLH} = 90^\circ</math>, and so <math>HT</math> is perpendicular to <math>AW</math> as well. Combining this with Lemma 3's statement, we deduce that <math>T, H, Y</math> are collinear. But, as <math>X</math> is on <math>YT</math> (from Lemma 1), <math>X, Y, H</math> are collinear. This completes the proof. |
<math>\blacksquare</math> | <math>\blacksquare</math> | ||
--[[User:Suli|Suli]] 13:51, 25 August 2014 (EDT) | --[[User:Suli|Suli]] 13:51, 25 August 2014 (EDT) | ||
+ | |||
+ | ==Solution 2== | ||
+ | Probably a simpler solution than above. | ||
+ | |||
+ | As above, let <math>T = \omega_1 \cap \omega_2 \neq W.</math> By Miquel <math>MTHN</math> is cyclic. Then since <math>\angle WCY = \angle WBX = 90^{\circ}</math> we know, because <math>W,B,X,T \in \omega_1</math> and <math>W,C,Y,T \in \omega_2,</math> that <math>\angle WTY = \angle WTX = 90^{\circ},</math> thus <math>X,T,Y</math> are collinear. | ||
+ | There are a few ways to finish. | ||
+ | |||
+ | (a) <cmath>BX \perp BC \perp AH \iff \angle NBX = \angle NAH</cmath> <cmath>\iff \angle NTX = \angle NTH \iff H \in TX</cmath>so <math>H,X,Y</math> are collinear, as desired <math>\square</math> | ||
+ | |||
+ | (b) Since <math>BNMC</math> is cyclic we know <math>AN \cdot AB = AM \cdot AC</math> which means <math>p(A,\omega_1) = p(A, \omega_2)</math> so <math>A</math> is on the radical axis, <math>TW,</math> hence <cmath>\angle ATX = \angle XBW = 90^{\circ} = \angle AMH = \angle ATH</cmath> so <math>H</math> lies on this line as well and we may conclude <math>\square</math> | ||
+ | |||
+ | --[[User:mathguy623|mathguy623]] 03:10, 12 August 2016 (EDT) | ||
+ | |||
+ | ==Solution 3 (Complex Bash)== | ||
+ | <asy> | ||
+ | unitsize(0.8cm); | ||
+ | draw((0,0)--(14,0)--cycle); | ||
+ | draw((0,0)--(5,12)--cycle); | ||
+ | draw((5,12)--(14,0)--cycle); | ||
+ | draw((2.071,4.97)--(14,0)--cycle); | ||
+ | draw((8.96,6.72)--(0,0)--cycle); | ||
+ | draw((2.071,4.97)--(9,0)--cycle); | ||
+ | draw((8.96,6.72)--(9,0)--cycle); | ||
+ | draw((0,0)--(0,2.083)--cycle); | ||
+ | draw((14,0)--(14,6.75)--cycle); | ||
+ | draw((0,2.083)--(14,6.75)--cycle); | ||
+ | draw((0,2.083)--(2.071,4.97)--cycle); | ||
+ | draw((0,2.083)--(9,0)--cycle); | ||
+ | draw((8.96,6.72)--(14,6.75)--cycle); | ||
+ | draw((14,6.75)--(9,0)--cycle); | ||
+ | |||
+ | draw(circle((4.5,1.0415),4.61895)); | ||
+ | draw(circle((11.5,3.375),4.20007)); | ||
+ | |||
+ | label((0,0),"$C$",SW); | ||
+ | label((14,0),"$B$",SE); | ||
+ | label((5,12),"$A$",N); | ||
+ | label((8.96,7),"$N$",N); | ||
+ | label((2.071,4.97),"$M$",NW); | ||
+ | label((8.25,0),"$W$",S); | ||
+ | label((5,4),"$H$",N); | ||
+ | label((0,2.083),"$Y$",NW); | ||
+ | label((14,6.75),"$X$",NE); | ||
+ | </asy> | ||
+ | |||
+ | For any point <math>P,</math> let <math>p</math> denote the complex number for point <math>P.</math> First off, let <math>C</math> be the origin. Now, since <math>WY</math> is the diameter of the circumcircle of triangle <math>CMW</math>, we must have <math>\angle{YMW}=\angle{YCH}=90^{\circ}.</math> Since angles inscribed in the same arc are congruent, <math>\angle{MYW}=\angle{MCW}=\angle{C}.</math> This means that <math>\frac{|w-m|}{|y-m|}=\tan{\angle{C}}.</math> Combining this with the fact that <math>\angle{YMW}</math> is right, we find that <cmath>i(y-m)\tan{\angle{C}}=(w-m).</cmath> Solving, we find that <cmath>y=\frac{w+(i\tan{\angle{C}}-1)m}{i\tan{\angle{C}}}.</cmath> We wish to simplify <math>(i\tan{\angle{C}}-1)m</math> first. Note that <cmath>m=\frac{|CM|}{|CA|}\cdot(a)=\frac{(|BC|)\cos{\angle{C}}}{|CA|}\cdot(|CA|)(\cos{\angle{C}}+i\sin{\angle{C}})=(|BC|)\cos{\angle{C}}(\cos{\angle{C}}+i\sin{\angle{C}}).</cmath> This means that | ||
+ | <cmath>\begin{align*} | ||
+ | (i\tan{\angle{C}}-1)m&=(i\tan{\angle{C}}-1)((|BC|)\cos{\angle{C}}(\cos{\angle{C}}+i\sin{\angle{C}}))\\ | ||
+ | &=\left(\frac{i\sin{\angle{C}}}{\cos{\angle{C}}}-1\right)((|BC|)\cos{\angle{C}}(\cos{\angle{C}}+i\sin{\angle{C}}))\\ | ||
+ | &=(i\sin{\angle{C}}-\cos{\angle{C}})(|BC|)(\cos{\angle{C}}+i\sin{\angle{C}})\\ | ||
+ | &=-|BC| | ||
+ | \end{align*}</cmath> | ||
+ | This means that <cmath>y=\frac{w-|BC|}{i\tan{\angle{C}}}=\frac{|BC|-w}{\tan{\angle{C}}}i.</cmath> Now, since <math>WX</math> is a diameter of the circumcircle of triangle <math>NBW,</math> we must have <math>\angle{WNX}=\angle{WBX}=90^{\circ}.</math> Since angles inscribed in the same arc are congruent, <math>\angle{NXW}=\angle{NBW}=\angle{B}.</math> This means that <math>\frac{|x-n|}{|w-n|}=\cot{\angle{B}}.</math> Combining this with the fact that <math>\angle{WNX}</math> is right, we find that <cmath>(x-n)=i\cot{\angle{B}}(w-n).</cmath> Solving, we find that <cmath>x=wi\cot{\angle{B}}+n(1-i\cot{\angle{B}}).</cmath> We wish to simplify <math>n(1-i\cot{\angle{B}})</math> first. Note that <cmath>n=e^{(90-\angle{B})i}|CN|=(\cos{(90-\angle{B})}+i\sin{(90-\angle{B})})(|BC|)\sin{\angle{B}}=(|BC|)\sin{\angle{B}}(\sin{\angle{B}}+i\cos{\angle{B}})).</cmath> This means that | ||
+ | <cmath>\begin{align*} | ||
+ | n(1-i\cot{\angle{B}})&=(|BC|)\sin{\angle{B}}(\sin{\angle{B}}+i\cos{\angle{B}}))(1-i\cot{\angle{B}})\\ | ||
+ | &=(|BC|)\sin{\angle{B}}(\sin{\angle{B}}+i\cos{\angle{B}}))\left(1-\frac{\cos{\angle{B}}}{\sin{\angle{B}}}i\right)\\ | ||
+ | &=(|BC|)(\sin{\angle{B}}+i\cos{\angle{B}})(\sin{\angle{B}}-i\cos{\angle{B}})\\ | ||
+ | &=(|BC|)(1) | ||
+ | \end{align*}</cmath> | ||
+ | This means that <cmath>x=|BC|+wi\cot{\angle{B}}=|BC|+\frac{w}{\tan{\angle{B}}}i.</cmath> This means that the line through complex numbers <math>x</math> and <math>y</math> satisfy the equation <cmath>\Im{(z)}=\left(\frac{\frac{w}{\tan{\angle{B}}}-\frac{|BC|-w}{\tan{\angle{C}}}}{|BC|}\right)\Re{(z)}+\frac{|BC|-w}{\tan{\angle{C}}}.</cmath> If there is a fixed point to the line, then the real and imaginary values of the point must not contin <math>w</math>. If the fixed point is <math>c,</math> then we have <cmath>\left(\frac{\frac{1}{\tan{\angle{B}}}+\frac{1}{\tan{\angle{C}}}}{|BC|}\right)\Re{(c)}-\frac{1}{\tan{\angle{C}}}=0,</cmath> after comparing the coefficient of <math>w.</math> This means that | ||
+ | <cmath>\begin{align*} | ||
+ | \Re{(c)}&=\frac{\frac{1}{\tan{\angle{C}}}}{\frac{\frac{1}{\tan{\angle{B}}}+\frac{1}{\tan{\angle{C}}}}{|BC|}}=\frac{\frac{\cos{\angle{C}}}{\sin{\angle{C}}}}{\frac{\frac{\cos{\angle{B}}}{\sin{\angle{B}}}+\frac{\cos{\angle{C}}}{\sin{\angle{C}}}}{|BC|}}\\ | ||
+ | &=\frac{\frac{\cos{\angle{C}}}{\sin{\angle{C}}}}{\frac{\frac{\cos{\angle{B}}\sin{\angle{C}}+\sin{\angle{B}}\cos{\angle{C}}}{\sin{\angle{B}}\sin{\angle{C}}}}{|BC|}}=\frac{\frac{\cos{\angle{C}}}{\sin{\angle{C}}}}{\frac{\sin{(\angle{B}+\angle{C})}}{|BC|\sin{\angle{B}}\sin{\angle{C}}}}\\ | ||
+ | &=\frac{\frac{\cos{\angle{C}}}{\sin{\angle{C}}}}{\frac{\sin{(180-\angle{A})}}{|BC|\sin{\angle{B}\sin{\angle{C}}}}}=\frac{|BC|\cos{\angle{C}}\sin{\angle{B}}\sin{\angle{C}}}{\sin{\angle{A}\sin{\angle{C}}}}\\ | ||
+ | &=\frac{|BC|}{\sin{\angle{A}}}\cdot(\cos{\angle{C}}\sin{\angle{B}}). | ||
+ | \end{align*}</cmath> | ||
+ | From the Law of Sines, we find that <cmath>\frac{|BC|}{\sin{\angle{A}}}=\frac{|AC|}{\sin{\angle{B}}}.</cmath> Substituting this, we find that | ||
+ | <cmath>\begin{align*} | ||
+ | \Re{(c)}&=\frac{|BC|}{\sin{\angle{A}}}\cdot(\cos{\angle{C}}\sin{\angle{B}})\\ | ||
+ | &=\frac{|AC|}{\sin{\angle{B}}}\cdot(\cos{\angle{C}}\sin{\angle{B}})\\ | ||
+ | &=|AC|\cos{\angle{C}}. | ||
+ | \end{align*}</cmath> | ||
+ | This means that | ||
+ | <cmath>\begin{align*} | ||
+ | \Im{(c)}&=\left(\frac{\frac{w}{\tan{\angle{B}}}-\frac{|BC|-w}{\tan{\angle{C}}}}{|BC|}\right)|AC|\cos{\angle{C}}+\frac{|BC|-w}{\tan{\angle{C}}}. | ||
+ | \end{align*}</cmath> | ||
+ | Since the <math>w</math>'s cancel out, we can just discard everything with <math>w</math> in it. Thus, | ||
+ | <cmath>\begin{align*} | ||
+ | \Im{(c)}&=\left(\frac{-\frac{|BC|}{\tan{\angle{C}}}}{|BC|}\right)|AC|\cos{\angle{C}}+\frac{|BC|}{\tan{\angle{C}}}\\ | ||
+ | &=\left(-\frac{1}{\tan{\angle{C}}}\right)|AC|\cos{\angle{C}}+\frac{|BC|}{\tan{\angle{C}}}\\ | ||
+ | &=\frac{1}{\tan{\angle{C}}}\left(|BC|-|AC|\cos{\angle{C}}\right). | ||
+ | \end{align*}</cmath> | ||
+ | Since <cmath>|BC|=|AC|\cos{\angle{C}}+|AB|\cos{\angle{B}},</cmath> we have <cmath>|BC|-|AC|\cos{\angle{C}}=|AB|\cos{\angle{B}}.</cmath> | ||
+ | Thus, <cmath>\Im{(c)}=\frac{1}{\tan{\angle{C}}}\cdot|AB|\cos{\angle{B}}.</cmath> In conclusion, <cmath>c=|AC|\cos{\angle{C}}+\left(\frac{1}{\tan{\angle{C}}}\cdot|AB|\cos{\angle{B}}\right)i,</cmath> which is the fixed point <math>XY</math> always passes through. However, by inspection, <math>c=H=\text{the orthocenter}.</math> Therefore, we conclude that <math>X,Y,H</math> are collinear for all acute triangles <math>ABC.</math> | ||
+ | |||
+ | ~pinkpig | ||
+ | |||
+ | ==See Also== | ||
+ | *[[2013 IMO]] | ||
+ | {{IMO box|year=2013|num-b=3|num-a=5}} |
Latest revision as of 00:31, 19 November 2023
Problem
Let be an acute triangle with orthocenter , and let be a point on the side , lying strictly between and . The points and are the feet of the altitudes from and , respectively. Denote by is the circumcircle of , and let be the point on such that is a diameter of . Analogously, denote by the circumcircle of triangle , and let be the point such that is a diameter of . Prove that and are collinear.
Hint
Draw a good diagram, or use the one below. What do you notice? (In particular, what do you want to be true? How do you prove it true?)
Solution 1
Let be the intersection of and other than .
Lemma 1: is on .
Proof: We have because they intercept semicircles. Hence, , so is a straight line.
Lemma 2: is on .
Proof: Let the circumcircles of and be and , respectively, and, as is cyclic (from congruent ), let its circumcircle be . Then each pair of circles' radical axises, and , must concur at the intersection of and , which is .
Lemma 3: is perpendicular to .
Proof: This is immediate from .
Let meet at , which is also the foot of the altitude to that side. Hence,
Lemma 4: Quadrilateral is cyclic.
Proof: We know that is cyclic because and , opposite and right angles, sum to . Furthermore, we are given that is cyclic. Hence, by Power of a Point,
The converse of Power of a Point then proves cyclic.
Hence, , and so is perpendicular to as well. Combining this with Lemma 3's statement, we deduce that are collinear. But, as is on (from Lemma 1), are collinear. This completes the proof.
--Suli 13:51, 25 August 2014 (EDT)
Solution 2
Probably a simpler solution than above.
As above, let By Miquel is cyclic. Then since we know, because and that thus are collinear. There are a few ways to finish.
(a) so are collinear, as desired
(b) Since is cyclic we know which means so is on the radical axis, hence so lies on this line as well and we may conclude
--mathguy623 03:10, 12 August 2016 (EDT)
Solution 3 (Complex Bash)
For any point let denote the complex number for point First off, let be the origin. Now, since is the diameter of the circumcircle of triangle , we must have Since angles inscribed in the same arc are congruent, This means that Combining this with the fact that is right, we find that Solving, we find that We wish to simplify first. Note that This means that This means that Now, since is a diameter of the circumcircle of triangle we must have Since angles inscribed in the same arc are congruent, This means that Combining this with the fact that is right, we find that Solving, we find that We wish to simplify first. Note that This means that This means that This means that the line through complex numbers and satisfy the equation If there is a fixed point to the line, then the real and imaginary values of the point must not contin . If the fixed point is then we have after comparing the coefficient of This means that From the Law of Sines, we find that Substituting this, we find that This means that Since the 's cancel out, we can just discard everything with in it. Thus, Since we have Thus, In conclusion, which is the fixed point always passes through. However, by inspection, Therefore, we conclude that are collinear for all acute triangles
~pinkpig
See Also
2013 IMO (Problems) • Resources | ||
Preceded by Problem 3 |
1 • 2 • 3 • 4 • 5 • 6 | Followed by Problem 5 |
All IMO Problems and Solutions |