Difference between revisions of "2011 AMC 12A Problems/Problem 25"
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== Problem == | == Problem == | ||
− | Triangle <math>ABC</math> has <math>\angle BAC = 60^{\circ}</math>, <math>\angle CBA \leq 90^{\circ}</math>, <math>BC=1</math>, and <math>AC \geq AB</math>. Let <math>H</math>, <math>I</math>, and <math>O</math> be the orthocenter, incenter, and circumcenter of <math>\triangle ABC</math>, | + | Triangle <math>ABC</math> has <math>\angle BAC = 60^{\circ}</math>, <math>\angle CBA \leq 90^{\circ}</math>, <math>BC=1</math>, and <math>AC \geq AB</math>. Let <math>H</math>, <math>I</math>, and <math>O</math> be the orthocenter, incenter, and circumcenter of <math>\triangle ABC</math>, respectively. Assume that the area of pentagon <math>BCOIH</math> is the maximum possible. What is <math>\angle CBA</math>? |
<math> | <math> | ||
Line 9: | Line 9: | ||
\textbf{(E)}\ 90^{\circ} </math> | \textbf{(E)}\ 90^{\circ} </math> | ||
− | == Solution == | + | == Solution 1 (MAA) == |
+ | |||
+ | By the Inscribed Angle Theorem, <cmath>\angle BOC = 2\angle BAC = 120^\circ .</cmath>Let <math>D</math> and <math>E</math> be the feet of the altitudes of <math>\triangle ABC</math> from <math>B</math> and <math>C</math>, respectively. In <math>\triangle ACE</math> we get <math>\angle ACE = 30^\circ</math>, and as exterior angle <cmath>\angle BHC = 90^\circ + \angle ACE = 120^\circ .</cmath>Because the lines <math>BI</math> and <math>CI</math> are bisectors of <math>\angle CBA</math> and <math>\angle ACB</math>, respectively, it follows that<cmath>\angle BIC = 90^\circ + \tfrac 12\angle A = 120^\circ .</cmath>Thus the points <math>B, C, O, I</math>, and <math>H</math> are all on a circle. | ||
+ | <asy> | ||
+ | import geometry; | ||
+ | size(200); | ||
+ | defaultpen(fontsize(12)+0.8); | ||
+ | |||
+ | pair O,A,B,C,D,E,I,H; | ||
+ | real h=2*sqrt(3); | ||
+ | O=(0,1/h); B=(-0.5,0); C=(0.5,0); | ||
+ | path c1=CR(O,length(O-B)); | ||
+ | // A=IP(c1,O--O+5*dir(120)); | ||
+ | A=IP(c1,B--B+5*dir(80)); | ||
+ | I=incenter(A,B,C); | ||
+ | H=orthocenter(A,B,C); | ||
+ | D=extension(A,C,B,H); E=extension(A,B,C,H); | ||
+ | path c2=circumcircle(O,I,H); | ||
+ | pair o2=circumcenter(O,I,H); | ||
+ | draw(c1, royalblue); draw(A--B--C--A); draw(B--D^^C--E, dotted); | ||
+ | draw(arc(o2,length(O-o2),10,170), dotted+red); draw(B--I--C--O--B, black+0.3); | ||
+ | pen p =black+3.25; | ||
+ | dot("$O$", O, N,p); dot("$A$", A, dir(110),p); dot("$B$", B, dir(210),p); dot("$C$", C, dir(-30),p); dot("$I$", I, N,p); dot("$H$", H, N,p); dot("$D$", D, D-H,p); dot("$E$", E, (E-C),p); | ||
+ | </asy> | ||
+ | Further, since | ||
+ | <cmath>\angle OCI = \angle OCB - \angle ICB = 30^\circ - \tfrac 12\angle C </cmath> | ||
+ | <cmath>\angle ICH = \angle ACE - \angle ACI = 30^\circ - \tfrac 12\angle C </cmath> | ||
+ | we have <math>OI=IH</math>. | ||
+ | |||
+ | Because <math>[BCOIH]=[BCO]+[BOIH]</math>, it is sufficient to maximize the area of quadrilateral <math>BOIH</math>. If <math>P_1</math>, <math>P_2</math> are two points in an arc of circle <math>BO</math> with <math>BP_1<BP_2</math>, then the maximum area of <math>BOP_1P_2</math> occurs when <math>BP_1=P_1P_2=P_2O</math>. Indeed, if <math>BP_1\neq P_1P_2</math>, then replacing <math>P_1</math> by the point <math>P_1’</math> located halfway in the arc of the circle <math>BP_2</math> yields a triangle <math>BP_1’P_2</math> with larger area than <math>\triangle BP_1P_2</math>, and the area of <math>\triangle BOP_2</math> remains the same. Similarly, if <math>P_1P_2\neq P_2O</math>. | ||
+ | |||
+ | Therefore the maximum is achieved when <math>OI=IH=HB</math>, that is, when <cmath>\angle OCI = \angle ICH = \angle HCB = \tfrac 13 \angle OCB = 10^\circ.</cmath>Thus <math>\angle ACB = 40^\circ</math> and <math>\angle CBA = 80^\circ</math>. | ||
+ | |||
+ | == Solution 2== | ||
+ | |||
+ | Let <math>\angle CAB=A</math>, <math>\angle ABC=B</math>, <math>\angle BCA=C</math> for convenience. | ||
+ | |||
+ | It's well-known that <math>\angle BOC=2A</math>, <math>\angle BIC=90+\frac{A}{2}</math>, and <math>\angle BHC=180-A</math> (verifiable by angle chasing). Then, as <math>A=60</math>, it follows that <math>\angle BOC=\angle BIC=\angle BHC=120</math> and consequently pentagon <math>BCOIH</math> is cyclic. Observe that <math>BC=1</math> is fixed, hence the circumcircle of cyclic pentagon <math>BCOIH</math> is also fixed. Similarly, as <math>OB=OC</math>(both are radii), it follows that <math>O</math> and also <math>[BCO]</math> is fixed. Since <math>[BCOIH]=[BCO]+[BOIH]</math> is maximal, it suffices to maximize <math>[BOIH]</math>. | ||
+ | |||
+ | Verify that <math>\angle IBC=\frac{B}{2}</math>, <math>\angle HBC=90-C</math> by angle chasing; it follows that <math>\angle IBH=\angle HBC-\angle IBC=90-C-\frac{B}{2}=\frac{A}{2}-\frac{C}{2}=30-\frac{C}{2}</math> since <math>A+B+C=180\implies\frac{A}{2}+\frac{B}{2}+\frac{C}{2}=90</math> by Triangle Angle Sum. Similarly, <math>\angle OBC=(180-120)/2=30</math> (isosceles base angles are equal), hence <cmath>\angle IBO=\angle IBC-\angle OBC=\frac{B}{2}-30=60-\frac{A}{2}-\frac{C}{2}=30-\frac{C}{2}</cmath> | ||
+ | Since <math>\angle IBH=\angle IBO</math>, <math>IH=IO</math> by Inscribed Angles. | ||
+ | |||
+ | There are two ways to proceed. | ||
+ | |||
+ | |||
+ | Letting <math>O'</math> and <math>R</math> be the circumcenter and circumradius, respectively, of cyclic pentagon <math>BCOIH</math>, the most straightforward is to write <math>[BOIH]=[OO'I]+[IO'H]+[HO'B]-[BO'O]</math>, whence <cmath>[BOIH]=\frac{1}{2}R^2(\sin(60-C)+\sin(60-C)+\sin(2C-60)-\sin(60))</cmath> and, using the fact that <math>R</math> is fixed, maximize <math>2\sin(60-C)+\sin(2C-60)</math> with Jensen's Inequality. | ||
+ | |||
+ | |||
+ | A more elegant way is shown below. | ||
+ | |||
+ | '''Lemma:''' <math>[BOIH]</math> is maximized only if <math>HB=HI</math>. | ||
+ | |||
+ | '''Proof by contradiction:''' Suppose <math>[BOIH]</math> is maximized when <math>HB\neq HI</math>. Let <math>H'</math> be the midpoint of minor arc <math>BI</math> be and <math>I'</math> the midpoint of minor arc <math>H'O</math>. Then <math>[BOIH']=[IBO]+[IBH']>[IBO]+[IBH]=[BOIH]</math> since the altitude from <math>H'</math> to <math>BI</math> is greater than that from <math>H</math> to <math>BI</math>; similarly <math>[BH'I'O]>[BOIH']>[BOIH]</math>. Taking <math>H'</math>, <math>I'</math> to be the new orthocenter, incenter, respectively, this contradicts the maximality of <math>[BOIH]</math>, so our claim follows. <math>\blacksquare</math> | ||
+ | |||
+ | With our lemma(<math>HB=HI</math>) and <math>IH=IO</math> from above, along with the fact that inscribed angles that intersect the same length chords are equal, | ||
+ | <cmath>\angle ABC=2\angle IBC=2(\angle OBC+\angle OBI)=2(30+\frac{1}{3}\angle OCB)=80\implies\boxed{(D)}</cmath> | ||
+ | |||
+ | ==Video Solution by Osman Nal== | ||
+ | https://www.youtube.com/watch?v=O3amRG9zEHE&ab_channel=OsmanNal | ||
+ | |||
== See also == | == See also == | ||
{{AMC12 box|year=2011|num-b=24|after=Last Problem|ab=A}} | {{AMC12 box|year=2011|num-b=24|after=Last Problem|ab=A}} | ||
+ | {{MAA Notice}} |
Latest revision as of 12:05, 28 June 2022
Problem
Triangle has , , , and . Let , , and be the orthocenter, incenter, and circumcenter of , respectively. Assume that the area of pentagon is the maximum possible. What is ?
Solution 1 (MAA)
By the Inscribed Angle Theorem, Let and be the feet of the altitudes of from and , respectively. In we get , and as exterior angle Because the lines and are bisectors of and , respectively, it follows thatThus the points , and are all on a circle. Further, since we have .
Because , it is sufficient to maximize the area of quadrilateral . If , are two points in an arc of circle with , then the maximum area of occurs when . Indeed, if , then replacing by the point located halfway in the arc of the circle yields a triangle with larger area than , and the area of remains the same. Similarly, if .
Therefore the maximum is achieved when , that is, when Thus and .
Solution 2
Let , , for convenience.
It's well-known that , , and (verifiable by angle chasing). Then, as , it follows that and consequently pentagon is cyclic. Observe that is fixed, hence the circumcircle of cyclic pentagon is also fixed. Similarly, as (both are radii), it follows that and also is fixed. Since is maximal, it suffices to maximize .
Verify that , by angle chasing; it follows that since by Triangle Angle Sum. Similarly, (isosceles base angles are equal), hence Since , by Inscribed Angles.
There are two ways to proceed.
Letting and be the circumcenter and circumradius, respectively, of cyclic pentagon , the most straightforward is to write , whence and, using the fact that is fixed, maximize with Jensen's Inequality.
A more elegant way is shown below.
Lemma: is maximized only if .
Proof by contradiction: Suppose is maximized when . Let be the midpoint of minor arc be and the midpoint of minor arc . Then since the altitude from to is greater than that from to ; similarly . Taking , to be the new orthocenter, incenter, respectively, this contradicts the maximality of , so our claim follows.
With our lemma() and from above, along with the fact that inscribed angles that intersect the same length chords are equal,
Video Solution by Osman Nal
https://www.youtube.com/watch?v=O3amRG9zEHE&ab_channel=OsmanNal
See also
2011 AMC 12A (Problems • Answer Key • Resources) | |
Preceded by Problem 24 |
Followed by Last Problem |
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All AMC 12 Problems and Solutions |
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