Difference between revisions of "1998 AIME Problems/Problem 12"
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[[Image:1998_AIME-12.png]] | [[Image:1998_AIME-12.png]] | ||
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+ | WLOG, assume that <math>AB = BC = AC = 2</math>. | ||
We let <math>x = EP = FQ</math>, <math>y = EQ</math>, <math>k = PQ</math>. Since <math>AE = \frac {1}{2}AB</math> and <math>AD = \frac {1}{2}AC</math>, <math>\triangle AED \sim \triangle ABC</math> and <math>ED \parallel BC</math>. | We let <math>x = EP = FQ</math>, <math>y = EQ</math>, <math>k = PQ</math>. Since <math>AE = \frac {1}{2}AB</math> and <math>AD = \frac {1}{2}AC</math>, <math>\triangle AED \sim \triangle ABC</math> and <math>ED \parallel BC</math>. | ||
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:<math> = 7 - 3\sqrt {5}</math></div> | :<math> = 7 - 3\sqrt {5}</math></div> | ||
We want the ratio of the squares of the sides, so <math>\frac {(2)^{2}}{k^{2}} = \frac {4}{7 - 3\sqrt {5}} = 7 + 3\sqrt {5}</math> so <math>a^{2} + b^{2} + c^{2} = 7^{2} + 3^{2} + 5^{2} = \boxed{083}</math>. | We want the ratio of the squares of the sides, so <math>\frac {(2)^{2}}{k^{2}} = \frac {4}{7 - 3\sqrt {5}} = 7 + 3\sqrt {5}</math> so <math>a^{2} + b^{2} + c^{2} = 7^{2} + 3^{2} + 5^{2} = \boxed{083}</math>. | ||
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+ | == Solution 2 == | ||
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+ | WLOG, let <math>\Delta ABC</math> have side length <math>2.</math> Then, <math>DE = EF = FD = 1.</math> We also notice that <math>\angle CEP = \angle DEF = 60^{\circ},</math> meaning <math>\angle CEF = \angle CEP + \angle DEF = 120^{\circ}.</math> | ||
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+ | Let <math>EP = x.</math> Since <math>FQ = x</math> by congruent triangles <math>\Delta EPC</math> and <math>\Delta FQA,</math> <math>EQ = EF - FQ = 1-x.</math> We can now apply Law of Cosines to <math>\Delta CEP, \Delta PEQ,</math> and <math>\Delta CEQ.</math> | ||
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+ | By LoC on <math>\Delta CEP,</math> we get <cmath>CP^2 = 1^2 + x^2 - 2\cdot 1\cdot x\cdot \left(\frac{1}{2}\right) = x^2 - x + 1.</cmath> | ||
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+ | In a similar vein, using LoC on <math>\Delta PEQ</math> and <math>\Delta CEQ,</math> respectively, earns <cmath>PQ^2 = x^2 + (1-x)^2 - 2\cdot x\cdot (1-x)\cdot \left(\frac{1}{2}\right) = 3x^2 - 3x + 1</cmath> <cmath>CQ^2 = 1^2 + (1-x)^2 - 2\cdot 1\cdot (1-x)\cdot \left(-\frac{1}{2}\right) = x^2 - 3x + 3</cmath> | ||
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+ | We have <math>CP^2, PQ^2,</math> and <math>CQ^2.</math> Additionally, by segment addition, <math>CP + PQ = CQ.</math> Solving for <math>CP, PQ,</math> and <math>CQ</math> from the Law of Cosines expressions and plugging them into the segment addition gets the (admittedly-ugly) equation <cmath>\sqrt{x^2-3x+3} = \sqrt{x^2-x+1} + \sqrt{3x^2-3x+1}.</cmath> | ||
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+ | Since the equation is ugly, we look at what the problem is asking for us to solve. We want <math>\frac{[ABC]}{[PQR]}.</math> We see that <math>[ABC] = \sqrt{3}</math> and <math>[PQR] = [DEF] - [PDR] - [RFQ] - [QEP] = \frac{\sqrt{3}}{4} - \frac{3}{2}\left(\frac{\sqrt{3}}{2}x(1-x)\right),</math> since <math>[PDR] = [RFQ] = [QEP] = \frac{1}{2}x(1-x)\frac{\sqrt{3}}{2}</math> from the sine area formula. Simplifying <math>\frac{[ABC]}{[PQR]}</math> gets us wanting to find <math>\frac{4}{3x^2-3x+1}.</math> | ||
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+ | We see <math>3x^2-3x+1</math> in both the denominator of what we want and under a radicand in our algebraic expression, which leads us to think the calculations may not be that bad. Isolate <math>\sqrt{3x^2-3x+1}</math> and square to get <cmath>3x^2-3x+1 = 2x^2-4x+4-2\sqrt{(x^2-3x+3)(x^2-x+1)}</cmath> | ||
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+ | Isolate the radicand and square and expand to get <math>x^4+2x^3-5x^2-6x+9=4x^4-16x^3+28x^2-24x+12,</math> and moving terms to one side and dividing by <math>3,</math> we get <cmath>x^4-6x^3+11x^2-6x+1=0.</cmath> | ||
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+ | This can be factored into <math>(x^2-3x+1)^2 = 0 \rightarrow x^2-3x+1 = 0 \rightarrow x = \frac{3 \pm \sqrt{5}}{2}.</math> From the equation <math>x^2-3x+1=0,</math> we have <math>x^2=3x+1,</math> so plugging that value into the expression we want to find, we get <math>\frac{4}{3(3x+1)-3x+1} = \frac{4}{6x+2}.</math> | ||
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+ | Substituting <math>x = \frac{3-\sqrt{5}}{2}</math> into <math>\frac{4}{6x+2}</math> gets an expression of <math>7+3\sqrt{5},</math> so <math>a^2+b^2+c^2 = \boxed{083}</math>. | ||
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+ | -PureSwag | ||
== See also == | == See also == |
Latest revision as of 13:33, 18 June 2024
Contents
Problem
Let be equilateral, and and be the midpoints of and respectively. There exist points and on and respectively, with the property that is on is on and is on The ratio of the area of triangle to the area of triangle is where and are integers, and is not divisible by the square of any prime. What is ?
Solution 1
WLOG, assume that .
We let , , . Since and , and .
By alternate interior angles, we have and . By vertical angles, .
Thus , so .
Since is equilateral, . Solving for and using and gives and .
Using the Law of Cosines, we get
We want the ratio of the squares of the sides, so so .
Solution 2
WLOG, let have side length Then, We also notice that meaning
Let Since by congruent triangles and We can now apply Law of Cosines to and
By LoC on we get
In a similar vein, using LoC on and respectively, earns
We have and Additionally, by segment addition, Solving for and from the Law of Cosines expressions and plugging them into the segment addition gets the (admittedly-ugly) equation
Since the equation is ugly, we look at what the problem is asking for us to solve. We want We see that and since from the sine area formula. Simplifying gets us wanting to find
We see in both the denominator of what we want and under a radicand in our algebraic expression, which leads us to think the calculations may not be that bad. Isolate and square to get
Isolate the radicand and square and expand to get and moving terms to one side and dividing by we get
This can be factored into From the equation we have so plugging that value into the expression we want to find, we get
Substituting into gets an expression of so .
-PureSwag
See also
1998 AIME (Problems • Answer Key • Resources) | ||
Preceded by Problem 11 |
Followed by Problem 13 | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 | ||
All AIME Problems and Solutions |
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