Difference between revisions of "2019 AMC 12A Problems/Problem 25"
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Note that quadrilateral <math>A_0B_0A_1B_1</math> is cyclic since <math>\angle A_0A_1B_0=\angle A_0B_1B_0=90^\circ</math>; thus, <math>\angle A_0A_1B_1=\angle A_0B_0B_1=90^\circ-x_0</math>. By a similar argument, <math>\angle A_0A_1C_1=\angle A_0C_0C_1=90^\circ-x_0</math>. Thus, <math>x_1=\angle A_0A_1B_1+\angle A_0A_1C_1=180^\circ-2x_0</math>. By a symmetric argument, <math>y_1=180^\circ-2y_0</math> and <math>z_1=180^\circ-2z_0</math>. | Note that quadrilateral <math>A_0B_0A_1B_1</math> is cyclic since <math>\angle A_0A_1B_0=\angle A_0B_1B_0=90^\circ</math>; thus, <math>\angle A_0A_1B_1=\angle A_0B_0B_1=90^\circ-x_0</math>. By a similar argument, <math>\angle A_0A_1C_1=\angle A_0C_0C_1=90^\circ-x_0</math>. Thus, <math>x_1=\angle A_0A_1B_1+\angle A_0A_1C_1=180^\circ-2x_0</math>. By a symmetric argument, <math>y_1=180^\circ-2y_0</math> and <math>z_1=180^\circ-2z_0</math>. | ||
− | Therefore, for any positive integer <math>n</math>, we have | + | Therefore, for any positive integer <math>n</math>, we have <math>x_n=180^\circ-2x_{n-1}</math> (identical recurrence relations can be derived for <math>y_n</math> and <math>z_n</math>). To find an explicit form for this recurrence, we guess that the constant term is related exponentially to <math>n</math> (and the coefficient of <math>x_0</math> is <math>(-2)^n</math>). Hence, we let <math>x_n=pq^n+r+(-2)^nx_0</math>. We will solve for <math>p</math>, <math>q</math>, and <math>r</math> by iterating the recurrence to obtain <math>x_1=180^\circ-2x_0</math>, <math>x_2=4x_0-180^\circ</math>, and <math>x_3=540-8x_0</math>. Letting <math>n=1,2,3</math> respectively, we have <cmath>\begin{align} |
+ | pq+r&=180 \\ | ||
+ | pq^2+r&=-180 \\ | ||
+ | pq^3+r&=540 | ||
+ | \end{align}</cmath> | ||
+ | |||
+ | Subtracting <math>(1)</math> from <math>(3)</math>, we have <math>pq(q^2-1)=360</math>, and subtracting <math>(1)</math> from <math>(2)</math> gives <math>pq(q-1)=-360</math>. Dividing these two equations gives <math>q+1=-1</math>, so <math>q=-2</math>. Substituting back, we get <math>p=-60</math> and <math>r=60</math>. Hence, for all positive integers <math>n</math>, <math>x_n=-60(-2)^n+60+(-2)^nx_0=(-2)^n(x_0-60)+60</math>, and the same holds for <math>y_n</math> and <math>z_n</math>. | ||
+ | |||
+ | The problem asks for the smallest <math>n</math> such that either <math>x_n</math>, <math>y_n</math>, or <math>z_n</math> is greater than <math>90^\circ</math>. WLOG, let <math>x_0=60^\circ</math>, <math>y_0=59.999^\circ</math>, and <math>z_0=60.001^\circ</math>. Thus, <math>x_n=60^\circ</math> for all <math>n</math>, <math>y_n=-(-2)^n(0.001)+60</math>, and <math>z_n=(-2)^n(0.001)+60</math>. Solving for the smallest possible value of <math>n</math> in each sequence, we find that <math>n=15</math> gives <math>y_n>90^\circ</math>. Therefore, the answer is \boxed{\bold (E) 15}}. | ||
==See Also== | ==See Also== |
Revision as of 21:42, 9 February 2019
Problem
Let be a triangle whose angle measures are exactly , , and . For each positive integer define to be the foot of the altitude from to line . Likewise, define to be the foot of the altitude from to line , and to be the foot of the altitude from to line . What is the least positive integer for which is obtuse?
Solution
For all nonnegative integers , let , , and .
Note that quadrilateral is cyclic since ; thus, . By a similar argument, . Thus, . By a symmetric argument, and .
Therefore, for any positive integer , we have (identical recurrence relations can be derived for and ). To find an explicit form for this recurrence, we guess that the constant term is related exponentially to (and the coefficient of is ). Hence, we let . We will solve for , , and by iterating the recurrence to obtain , , and . Letting respectively, we have
Subtracting from , we have , and subtracting from gives . Dividing these two equations gives , so . Substituting back, we get and . Hence, for all positive integers , , and the same holds for and .
The problem asks for the smallest such that either , , or is greater than . WLOG, let , , and . Thus, for all , , and . Solving for the smallest possible value of in each sequence, we find that gives . Therefore, the answer is \boxed{\bold (E) 15}}.
See Also
2019 AMC 12A (Problems • Answer Key • Resources) | |
Preceded by Problem 24 |
Followed by Last Problem |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 • 16 • 17 • 18 • 19 • 20 • 21 • 22 • 23 • 24 • 25 | |
All AMC 12 Problems and Solutions |
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