(a) A bungee jumper of height 2 m falls from a bridge which is 125 m above the surface of the water, as shown in the diagram - HSC - SSCE Mathematics Extension 2 - Question 7 - 2009 - Paper 1

Given that $g = 9.8 \, m \, s^{-2}$ and $r = 0.2 \, s^{-1}$, to find L such that the jumper's velocity is 30 m/s:

1. Start with the derived expression for velocity at $x = L$: $v = \frac{g}{r} (1 - e^{-rL})$. Setting $v = 30$ m/s gives:

   $30 = \frac{9.8}{0.2} (1 - e^{-0.2L}).$

2. Solve for $L$:

   $30 = 49 (1 - e^{-0.2L})$ $1 - e^{-0.2L} = \frac{30}{49},$ thus, $e^{-0.2L} = 1 - \frac{30}{49} = \frac{19}{49}.$

3. By taking the natural logarithm, we find: $-0.2L = \ln{\left(\frac{19}{49}\right)}$ and solving gives: $L = -\frac{\ln{\left(\frac{19}{49}\right)}}{0.2}.$

4. Calculate the numerical value and round to two significant figures.

In the second stage where $x > L$, use the given equation:

$x = e^{\frac{t}{10}}(29\sin{t} - 10\cos{t}) + 92.$

1. Determine the maximum value of the function $29\sin{t} - 10\cos{t}$, which is at least: $\sqrt{29^2 + (-10)^2} = \sqrt{841} = 29.$

2. Thus, the maximum displacement $x$ becomes: $x_{max} = e^{\frac{t}{10}}(29) + 92.$

3. Check for the head height:

   $$$$

ightarrow ?$$

4. Calculate it out to see if $x$ is less than or equal to 125 to determine if the jumper's head will be above water.