Problem:
A tripod has three legs each of length 5 feet. When the tripod is set up, the angle between any pair of legs is equal to the angle between any other pair, and the top of the tripod is 4 feet from the ground. In setting up the tripod, the lower 1 foot of one leg breaks off. Let h be the height in feet of the top of the tripod from the ground when the broken tripod is set up. Then h can be written in the form nβmβ, where m and n are positive integers and n is not divisible by the square of any prime. Find βm+nββ. (The notation βxβ denotes the greatest integer that is less than or equal to x.)
Solution:
The feet of the unbroken tripod are the vertices of an equilateral triangle ABC, and the foot of the perpendicular from the top to the plane of this triangle is at the center of the triangle. By the Pythagorean Theorem, the distance from the center to each vertex of the triangle is 3 . Place a coordinate system so that the coordinates of the top T are (0,0,4) and the coordinates of A,B, and C are (3,0,0),(β3/2,33β/2,0), and (β3/2,β33β/2,0), respectively. Let the break point Aβ² be on TA. Then TAβ²:Aβ²A=4:1. Thus the coordinates of Aβ² are
54β(3,0,0)+51β(0,0,4)=(12/5,0,4/5)
Note that the coordinates of M, the midpoint of BC, are (β3/2,0,0). The perpendicular from T to the plane of β³Aβ²BC will intersect this plane at a point on MAβ². This segment lies in the xz-plane and has equation 8xβ39z+12=0 in this plane. Then h is the distance from T to line MAβ², and is equal to
Place a coordinate system as in the first solution. Note that β³Aβ²MT is in the xz-plane. In this plane, circumscribe a rectangle around β³Aβ²MT with its sides parallel to the axes. Then
Thus h=Aβ²M2[Aβ²MT]β=15.85β14.4β=1585β144β, so βm+nββ=144+39=183β.
OR
The feet of the unbroken tripod are the vertices of an equilateral triangle ABC, and the foot of the perpendicular from the vertex to the plane of this triangle is at the center of the triangle. Let T be the top of the tripod, let O be the center of β³ABC, let Aβ² be the break point on TA, and let M be the midpoint of BC. Apply the Pythagorean Theorem to β³TOA to conclude that OA=3. Therefore β³ABC has sides of length 33β. Notice that Aβ²,M, and T are all equidistant from B and C, so the plane determined by β³TAβ²M is perpendicular to BC, and so h is the length of the altitude from T in β³TAβ²M. Because
The length of Aβ²T is 4, and TM=TB2βBM2β=25β(27/4)β=73β/2. To find Aβ²M, note that Aβ²M2=Aβ²C2βCM2, and that Aβ²C2=Aβ²T2+TC2β2Aβ²Tβ TCcosβ Aβ²TC.
But cosβ Aβ²TC=cosβ ATC=2β 5β 552+52β(33β)2β=5023β,
so Aβ²C2=42+52β2β 4β 5β (23/50)=113/5, and Aβ²M=5113ββ427ββ=20317ββ.
Now cosβ Aβ²TM=2β 4β 73β/216+73/4β317/20β=573β23β,
so sin2β Aβ²TM=1β25β 73232β, and sinβ Aβ²TM=573β36β. Thus
