Problem:
Square ABCD has sides of length 1. Points E and F are on BC and CD, respectively, so that β³AEF is equilateral. A square with vertex B has sides that are parallel to those of ABCD and a vertex on AE. The length of a side of this smaller square is caβbββ, where a,b, and c are positive integers and b is not divisible by the square of any prime. Find a+b+c.
Solution:
Let CF=x. Then, because β³ADFβ β³ABE, it follows that DF=BE=1βx, and CE=x. Hence 2x2=EF2=AE2=(1βx)2+1, and so x=3ββ1. Let P and Q be the vertices of the smaller square that are on AE and AB, respectively. Then
PQABβPQβPQABβPQ1ββ=PQABβBQβ=PQAQβ=BEABβ, so =1+BEABβ, and =AB1β+BE1β.β
Thus PQ1β=1+1β(3ββ1)1β=1+2β3β1β=1+2+3β=3+3β. Consequently PQ=3+3β1β=63β3ββ, and a+b+c=12
OR
Let BOPQ be the smaller square, where Q is between A and B, and let BQ=y. Then QP=y, and AQ=ytan75β. Thus 1=AB=AQ+QB=ytan75β+y, so y=1+tan75β1β. But tan75β=tan(45β+30β)=1β(1/3β)1+(1/3β)β=2+3β. Therefore y=3+3β1β=63β3ββ.
OR
Place a coordinate system so that A is the origin, and the coordinates of B,C, and D are (1,0),(1,1), and (0,1), respectively. Let BE=p. Then, as in the first solution, p=1β(3ββ1)=2β3β. Hence line AE has slope 2β3β and contains the origin. Thus line AE has equation y=(2β3β)x. Let q be the length of a side of the smaller square. Then one vertex of that square has coordinates (1βq,q) and is on line AE. Therefore q=(2β3β)(1βq), which yields q=(3β3β)/6.
