Problem:
Equilateral β³ABC has side length 600. Points P and Q lie outside the plane of β³ABC and are on the opposite sides of the plane. Furthermore, PA=PB=PC, and QA=QB=QC, and the planes of β³PAB and β³QAB form a 120β dihedral angle (the angle between the two planes). There is a point O whose distance from each of A,B,C,P, and Q is d. Find d.
Solution:
Let H be the foot of the perpendicular from P to the plane of β³ABC. Because PA=PB=PC, it follows that HA=HB=HC; that is, H is the centroid of the equilateral β³ABC. Likewise H is also the foot of the perpendicular from Q to the plane of β³ABC. Hence O is the midpoint of PQβ and PQ=2d.
Let D be the midpoint of side AB. Hence PDβ₯AB and QDββ₯AB, from which it follows that β PDQ is the angle formed by planes ABP and ABQ, and so β PDQ=120β. Let β PDH=x and β QDH=y. Then tan(x+y)=β3β. Set AB=a. Then DC=23βaβ,DH=31βDC=63βaβ, and PH=tanxβ DH=63βaβtanx. Likewise QH=63βaβtany. Hence 2d=PQ=PH+HQ=63βaβ(tanx+tany), or
tanx+tany=a43βdβ
Because OP=OC=OQ, conclude that O, the midpoint of PQβ, is the circumcenter of β³PCQ, from which it follows that β PCQ=90β. Then CH is the altitude to the hypotenuse of right β³CPQ, implying that CH2=PHβ QH. Hence
CH2=(32βDC)2=3a2β=PHβ HQ=12a2tanxtanyβ
implying that tanxtany=4.
By the Tangent Angle Addition Formula, tan(x+y)=1βtanxtanytanx+tanyβ or
β3β=1β4a43βdββ
implying that d=43aβ. Substituting a=600 in the last equation yields d=450β.