2. (a) By using the substitution $t = \tan\frac{\theta}{2}$, show that \( \frac{1 - \cos\theta}{\sin\theta} = \tan\frac{\theta}{2} \) - HSC - SSCE Mathematics Extension 1 - Question 2 - 2007 - Paper 1

To sketch the graph of ( y = f(x) = 2\cos^{-1} x ):

1. Identify the domain: ( -1 \leq x \leq 1 ).
2. The endpoints are at ( (1, 0) ) and ( (-1, 2\pi) ) since ( \cos^{-1}(x) ) ranges from 0 to ( \pi ).
3. Graph the function, a decreasing curve from ( (1, 0) ) to ( (-1, 2\pi) ).

The range of ( f(x) = 2\cos^{-1} x ) is ( [0, 2\pi] ).

Given ( P(2) = 0 ): [ P(2) = 2^2 + 2a + b = 0 \rightarrow 4 + 2a + b = 0 \rightarrow b = -4 - 2a. ] From the Remainder Theorem, when ( P(x) ) is divided by ( x + 1 ): [ P(-1) = (-1)^2 + (-1)a + b = 1 - a + b = 18 \rightarrow 1 - a - 4 - 2a = 18 \rightarrow -3 - 3a = 18 \rightarrow a = -7. ] Substituting back: [ b = -4 - 2(-7) = -4 + 14 = 10.
] Thus, ( a = -7 ) and ( b = 10 ).

The velocity function is ( v = 50(1 - e^{-2t}) ). To find acceleration, differentiate: [ a(t) = \frac{dv}{dt} = 50 \cdot 2e^{-2t} = 100e^{-2t}. ] At ( t = 10 ): [ a(10) = 100e^{-20} \approx 0.0000454 \text{ (very small)} \approx 0.0.
]

To find the distance ( s ) fallen, integrate the velocity function: [ s(t) = \int_{0}^{t} v dt = \int_{0}^{10} 50(1 - e^{-2t}) dt. ] Calculating: [ s(10) = [50t + 25e^{-2t}]_{0}^{10} = 50(10) - 25e^{-20} - (0 -25) = 500 + 25 \approx 525 ext{ metres.} \