An angler casts a fishing line so that the sinker is projected with a speed V m s$^{-1}$ from a point 5 metres above a flat sea - HSC - SSCE Mathematics Extension 1 - Question 6 - 2002 - Paper 1

To find the value of $V$ when the sinker hits the sea:

1. From the horizontal motion, we know: $x = 60 = Vt \, ext{cos} \, \theta$

2. Given that $heta = \tan^{-1} \frac{3}{4}$, we can calculate:

   $$$$

ightarrow \text{cos} \theta = \frac{4}{5} , ext{and} , \text{sin} \theta = \frac{3}{5} $$

3. Replacing in our earlier equation, we get: $60 = Vt \frac{4}{5}$

4. Rearranging gives: $V = \frac{60 \cdot 5}{4t} = \frac{75}{t}$

5. From the vertical motion when $y = 0$: $0 = 5 + Vt \frac{3}{5} - 5t^2$ Setting $y = 0$ leads to: $0 = 5 + \frac{75t}{t} \cdot \frac{3}{5} - 5t^2$

6. This leads to a quadratic equation which can be solved for $t$, then used to find $V$.

The maximum height occurs when the vertical velocity is zero:

1. Vertical velocity is given by: $v_y = V \sin(\theta) - g t$
   Setting $v_y = 0$, we obtain: $g t = V \sin(\theta)$ So, $t = \frac{V \cdot \sin(\theta)}{g}$

2. Substitute this time into the height equation: $y_{max} = 5 + V \sin(\theta) t - 5t^2$

3. Finally plug the obtained value of $t$ into this equation to compute $y_{max}$ and identify the height.