66 CHAPTER 3 TACTICS FOR SOLVING PROBLEMS
ThusConsequently, the value that we seek isThe next problem, from the 1995 IMO, is harder than the others, but only in a
"technical" way. In order to solve it, you need to be familiar with Ptolemy's Theorem,
which statesLet ABCD be a cyclic quadrilateral, i.e., a quadrilateral whose vertices
lie on a circle. ThenAB·CD +AD· BC =AC·BD.cSee Problems 4.2.41, 8.4.30, and 8.5.49 for different ideas for a proof. A key feature
of cyclic quadrilaterals is the easily verified fact (see page 266) that
A quadrilateral is cyclic if and only if its opposite angles are supple
mentary (add up to 180 degrees).Example 3.1. 8 Let ABCDEF be a convex hexagon with AB = BC = CD and DE =EF =FA, such that L.BCD = L.EFA = 1C/3. Suppose G andH are points in the interior
of the hexagon such that LAGB = L.DHE = 21C/3. Prove that
AG+GB+GH +DH +HE 2: CF.Solution: First, as for all geometry problems, draw an accurate diagram, using
pencil, compass and ruler. Look for symmetry. Note that BCD and EFA are equilateral
triangles, so that BD = BA and DE = AE. By the symmetry of the figure, it is seems
profitable to reflect about BE. Let C' and F' be the reflections of C and F respectively.