Difference between revisions of "Mock Geometry AIME 2011 Problems/Problem 13"
(Created page with "==Problem 13== In acute triangle <math>ABC,</math> <math>\ell</math> is the bisector of <math>\angle BAC</math>. <math>M</math> is the midpoint of <math>BC</math>. a line thr...") |
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==Solution== | ==Solution== | ||
− | Solving the problem involves the ambiguous case of law of sines. First part of solution is angle chasing. Let <math>L</math> be intersection of angle bisector <math>\ell</math> with <math>BC</math> Let <math>\angle BAL</math> be <math>\theta</math>, and <math>\angle LAC is \theta</math> as well, since angle bisector. Since line through <math>M</math> is parallel to <math>\ell</math>, <math>\angle MEC</math> is also <math>\theta</math>. Let <math>\angle BLA</math> then be <math>\alpha</math>, and by parallel lines, <math>\angle BME</math> is also <math>\alpha</math>. Doing further angle chasing, we find that <math>AFE</math> is isoceles with base <math>EF</math>. Using <math>30-60-90</math> triangle ratio, we find <math>\theta = 30^\circ</math> | + | Solving the problem involves the ambiguous case of law of sines. First part of solution is angle chasing. Let <math>L</math> be intersection of angle bisector <math>\ell</math> with <math>BC</math> Let <math>\angle BAL</math> be <math>\theta</math>, and <math>\angle LAC</math> is <math>\theta</math> as well, since angle bisector. Since line through <math>M</math> is parallel to <math>\ell</math>, <math>\angle MEC</math> is also <math>\theta</math>. Let <math>\angle BLA</math> then be <math>\alpha</math>, and by parallel lines, <math>\angle BME</math> is also <math>\alpha</math>. Doing further angle chasing, we find that <math>AFE</math> is isoceles with base <math>EF</math>. Using <math>30-60-90</math> triangle ratio, we find <math>\theta = 30^\circ</math> |
There are two possible configurations of the triangle, one such that <math>L</math> is to the left of <math>M</math>, and vice versa. In the first <math>A</math> falls between <math>B</math> and <math>F</math>, with <math>F</math> outside the triangle, and in the second <math>F</math> between <math>B</math> and <math>A</math>, with <math>E</math> outside the triangle. Using Law of Sines then: | There are two possible configurations of the triangle, one such that <math>L</math> is to the left of <math>M</math>, and vice versa. In the first <math>A</math> falls between <math>B</math> and <math>F</math>, with <math>F</math> outside the triangle, and in the second <math>F</math> between <math>B</math> and <math>A</math>, with <math>E</math> outside the triangle. Using Law of Sines then: | ||
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Solving for the ratio of <math>BL : LC</math> on both triangles, and then applying Angle Bisector theorem yields a <math>21,23</math> with included angle <math>60^\circ</math> for <math>[1]</math> and <math>21,19</math> with included angle <math>60^\circ</math> for <math>[2]</math>. Solving using Law of Cosine yields answer of <math>\sqrt{487}</math> and <math>\sqrt{403}</math>, or <math>\boxed{890}</math>. | Solving for the ratio of <math>BL : LC</math> on both triangles, and then applying Angle Bisector theorem yields a <math>21,23</math> with included angle <math>60^\circ</math> for <math>[1]</math> and <math>21,19</math> with included angle <math>60^\circ</math> for <math>[2]</math>. Solving using Law of Cosine yields answer of <math>\sqrt{487}</math> and <math>\sqrt{403}</math>, or <math>\boxed{890}</math>. | ||
+ | |||
+ | ==Video Solution by MOP 2024== | ||
+ | https://youtu.be/dVzdLGHMTUc | ||
+ | |||
+ | ~r00tsOfUnity |
Latest revision as of 14:49, 12 July 2023
Problem 13
In acute triangle is the bisector of . is the midpoint of . a line through parallel to meets at respectively. Given that the sum of all possible values of can be expressed as where are positive integers. What is ?
Solution
Solving the problem involves the ambiguous case of law of sines. First part of solution is angle chasing. Let be intersection of angle bisector with Let be , and is as well, since angle bisector. Since line through is parallel to , is also . Let then be , and by parallel lines, is also . Doing further angle chasing, we find that is isoceles with base . Using triangle ratio, we find
There are two possible configurations of the triangle, one such that is to the left of , and vice versa. In the first falls between and , with outside the triangle, and in the second between and , with outside the triangle. Using Law of Sines then:
Plugging in values, we find for acute and obtuse triangles denoted as and , respectively,
, and
Using Law of Sines again and substituting the expression for the and for ,
, and
Solving for the ratio of on both triangles, and then applying Angle Bisector theorem yields a with included angle for and with included angle for . Solving using Law of Cosine yields answer of and , or .
Video Solution by MOP 2024
~r00tsOfUnity