Applying Menelaus' theorem to ΔBCF with AD as the transversal, we have
$latex (\frac {BD}{DC} \frac {CA}{AF} \frac {FP}{PB})$ = 1
But BD/DC = 1/2 (as BD = DE = EC) and CA/AF = 2/1 (as CF = FA).
Hence we have BP = PF.
Again applying Menelaus' Theorem to ΔBCF with AE as the transversal we have $latex (\frac {BE}{EC} \frac {CA}{AF} \frac {FQ}{QB})$ = 1
But BE/EC = 2/1 and CA/AF = 2/1
Hence 4FQ = QB.
Suppose FQ= x unit. The QB = 4x unit. That is BF = 5x unit. Since BP = PF hence each is 2.5x unit.
Thus PQ = 2.5x - x = 1.5x unit
Hence $latex (\frac {\triangle APQ}{\triangle ABF})$ = $latex (\frac {1.5x}{5x})$
Also $latex (\frac {\triangle ABF}{\triangle ABC} = \frac {1}{2})$
Thus $latex (\frac {\triangle APQ}{\triangle ABF}$ = $latex (\frac {\triangle ABF}{\triangle ABC})$ = \( \frac {1.5x}{5x} \frac {1}{2}\) = $latex (\frac {\triangle APQ}{\triangle ABC})$ = $latex (\frac {1.5}{10})$ ...(1)
Again \( \frac {\triangle ADE}{\triangle ABC}\) = $latex (\frac {1}{3})$ (as DE/BC = 1/3)
Thus \( \frac {\triangle ADE}{\triangle ABC} - \frac {\triangle APQ}{\triangle ABC} = \frac {1}{3} - \frac {1.5}{10}\)
$latex (\frac {PQED}{\triangle ABC} = \frac {5.5}{30})$ ...(2)
Using (1) and (2) we have $latex (\frac {\triangle APQ}{PQED} = \frac {4.5}{5.5} = \frac {9}{11})$
