(a) 1 : 2
P and Q being the mid-points of AC and AB respectively, PQ || BC and PQ = \(\frac{1}{2}\) BC
Let AF ⊥ BC be drawn such that it intersects PQ and BC in E and F respectively.
PQ || BC ⇒ \(\frac{AE}{EF}=\frac{AP}{PC} = 1\) ⇒ AE = EF
Also let RI ⊥ PQ be drawn such that it intersect BC and PQ in J and I respectively. G and H being the mid-points of sides PR and RQ of ΔPQR, GH || PQ and GH = \(\frac{1}{2}\) PQ
(By midpoint Theorem)
Also, GH || PQ ⇒ \(\frac{RJ}{JI}=\frac{RG}{GP}=1\) ⇒ RJ = RG
(By Basic Proportionality Theorem)
But EF = JI
∴ AE = EF = RJ = JI
∴ AF = AE + EF = RJ + JI = RI = h (say)
Then, \(\frac{\text{Area (ΔPQR)}}{\text Area (ΔABC)}\) = \(\frac{\frac{1}{2}\times{PQ}\times{h}}{\frac{1}{2}\times{BC}\times{h}}=\frac{PQ}{BC}=\frac{1}{2}.\)
