Problem:
In triangle ABC,AB=10,BC=14, and CA=16. Let D be a point in the interior of BC. Let IBβ and ICβ denote the incenters of triangles ABD and ACD, respectively. The circumcircles of triangles BIBβD and CICβD meet at distinct points P and D. The maximum possible area of β³BPC can be expressed in the form aβbcβ, where a,b and c are positive integers and c is not divisible by the square of any prime. Find a+b+c.
The points P and IBβ must lie on opposite sides of BC, and BIBβDP and CICβDP are convex cyclic quadrilaterals. If P and IBβ were on the same side, then both BIBβPD and CICβPD would be convex. It would then follow by (1) and the fact that quadrilaterals BIBβPD and CICβPD are cyclic that
Therefore, β BPC is constant, and so P lies on the arc of a circle passing through B and C.
The Law of Cosines yields cosβ BAC=2β 10β 16102+162β142β=21β, and so β BAC=60β. Hence β BPC=150β, and the minor arc subtended by the chord BC measures 60β. Thus the radius of the circle is equal to BC=14. The maximum area of β³BPC occurs when BP=PC. Applying the Law of Cosines to β³BPC with BP=PC=x yields 142=2x2+x23β, so x2=2+3β196β=196(2β3β). The area of this triangle is 21βx2sin150β=98β493β, and so a+b+c=150β.
