Problem:
In β³ABC,AB=20. The incircle of the triangle divides the median containing C into three segments of equal length. Given that the area of β³ABC is mnβ, where m and n are integers and n is not divisible by the square of any prime, find m+n.
Solution:
Let M be the midpoint of AB, and let S and N be the points where median CM meets the incircle, with S between C and N. Let AC and AB touch the incircle at R and T, respectively. Assume, without loss of generality, that T is between A and M. Then AR=AT. Use the Power-of-a-Point Theorem to conclude that
MT2=MNβ MS and CR2=CSβ CN
Because CS=SN=MN, conclude that CR=MT, and
AC=AR+CR=AT+MT=AM=21βAB=10
Let s=(1/2)(AB+BC+CA). Then AT=sβBC, and
MT=MAβAT=21βABβs+BC=2BCβACβ=2BCβ10β
But MT2=MNβ MS=(2/9)CM2, so 2BCβ10β=CMβ 32ββ. Hence
CM=22β3ββ (BCβ10)
Apply the Law of Cosines to triangles AMC and ABC to obtain
Then BC2=100+2β CM2, so BC2=100+(9/4)(BCβ10)2. The solutions of this equation are 26 and 10, but BC>ABβAC=10. It follows that BC=26, and then that CM=122β. The length of the altitude from A in isosceles β³AMC is therefore 27β. Thus [ABC]=2[AMC]=2414β, and m+n=38β.
