Difference between revisions of "2011 AIME I Problems/Problem 10"
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== Problem == | == Problem == | ||
The probability that a set of three distinct vertices chosen at random from among the vertices of a regular n-gon determine an obtuse triangle is <math>\frac{93}{125}</math> . Find the sum of all possible values of <math>n</math>. | The probability that a set of three distinct vertices chosen at random from among the vertices of a regular n-gon determine an obtuse triangle is <math>\frac{93}{125}</math> . Find the sum of all possible values of <math>n</math>. |
Revision as of 16:01, 9 August 2018
Contents
[hide]Problem
The probability that a set of three distinct vertices chosen at random from among the vertices of a regular n-gon determine an obtuse triangle is . Find the sum of all possible values of .
Solution 1
Inscribe the regular polygon inside a circle. A triangle inside this circle will be obtuse if and only if its three vertices lie on one side of a diameter of the circle. (This is because if an inscribed angle on a circle is obtuse, the arc it spans must be 180 degrees or greater).
Break up the problem into two cases: an even number of sides , or an odd number of sides . For polygons with sides, the circumdiameter has endpoints on vertices. There are points on one side of a diameter, plus of the endpoints of the diameter for a total of points. For polygons with points, the circumdiameter has endpoint on a vertex and endpoint on the midpoint of the opposite side. There are also points on one side of the diameter, plus the vertex for a total of points on one side of the diameter.
Case 1: -sided polygon. There are clearly different triangles total. To find triangles that meet the criteria, choose the left-most point. There are obviously choices for this point. From there, the other two points must be within the points remaining on the same side of the diameter. So our desired probability is
so
.
and so the polygon has sides.
Case 2: -sided polygon. Similarly, total triangles. Again choose the leftmost point, with choices. For the other two points, there are again possibilities.
The probability is
so
and our polygon has sides.
Adding,
Solution 2
We use casework on the locations of the vertices, if we choose the locations of vertices on the n-gon (where the vertices of the n-gon are in clockwise order) to be the vertices of triangle ABC, in order, with the restriction that .
By symmetry, we can assume W/O LOG that the location of vertex A is vertex .
Now, vertex B can be any of . We start in on casework.
Case 1: vertex B is at one of the locations . (The ceiling function is necessary for the cases in which n is odd.)
Now, since the clockwise arc from A to B measures more than 180 degrees; for every location of vertex C we can choose in the above restrictions, angle C will be an obtuse angle.
There are choices for vertex B now (again, the ceiling function is necessary to satisfy both odd and even cases of n). If vertex B is placed at , there are possible places for vertex C.
Summing over all these possibilities, we obtain that the number of obtuse triangles obtainable from this case is .
Case 2: vertex B is at one of the locations not covered in the first case.
Note that this will result in the same number of obtuse triangles as case 1, but multiplied by 2. This is because fixing vertex B in , then counting up the cases for vertices C, and again for vertices C and A, respectively, is combinatorially equivalent to fixing vertex A at , then counting cases for vertex B, as every triangle obtained in this way can be rotated in the n-gon to place vertex A at , and will not be congruent to any obtuse triangle obtained in case 1, as there will be a different side opposite the obtuse angle in this case.
Therefore, there are total obtuse triangles obtainable.
The total number of triangles obtainable is .
The ratio of obtuse triangles obtainable to all triangles obtainable is therefore
.
So, .
Now, we have that is divisible by . It is now much easier to perform trial-and-error on possible values of n, because we see that .
We find that and both work, so the final answer is .
See also
2011 AIME I (Problems • Answer Key • Resources) | ||
Preceded by Problem 9 |
Followed by Problem 11 | |
1 • 2 • 3 • 4 • 5 • 6 • 7 • 8 • 9 • 10 • 11 • 12 • 13 • 14 • 15 | ||
All AIME Problems and Solutions |
The problems on this page are copyrighted by the Mathematical Association of America's American Mathematics Competitions.