Routh's theorem
In geometry, Routh's theorem determines the ratio of areas between a given triangle and a triangle formed by the pairwise intersections of three cevians. The theorem states that if in triangle A B C {\displaystyle ABC} points D {\displaystyle D} , E {\displaystyle E} , and F {\displaystyle F} lie on segments B C {\displaystyle BC} , C A {\displaystyle CA} , and A B {\displaystyle AB} , then writing C D B D = x {\displaystyle {\tfrac {CD}{BD}}=x} , A E C E = y {\displaystyle {\tfrac {AE}{CE}}=y} , and B F A F = z {\displaystyle {\tfrac {BF}{AF}}=z} , the signed area of the triangle formed by the cevians A D {\displaystyle AD} , B E {\displaystyle BE} , and C F {\displaystyle CF} is S A B C ( x y z − 1 ) 2 ( x y + y + 1 ) ( y z + z + 1 ) ( z x + x + 1 ) , {\displaystyle S_{ABC}{\frac {(xyz-1)^{2}}{(xy+y+1)(yz+z+1)(zx+x+1)}},} where S A B C {\displaystyle S_{ABC}} is the area of the triangle A B C {\displaystyle ABC} .