4 (15 marks) Use a SEPARATE writing booklet - HSC - SSCE Mathematics Extension 2 - Question 4 - 2010 - Paper 1

When sketching the curve defined by $\sqrt{x} + \sqrt{y} = 1$, we first identify the intercepts:

• Setting $y = 0$, we find $x = 1$.
• Setting $x = 0$, we find $y = 1$.

The points $(1, 0)$ and $(0, 1)$ define the axes. The curve is thus bounded by these points and is composed in the first quadrant, curving downwards towards the axes.

For the curve $\sqrt{|x|} + \sqrt{|y|} = 1$, the approach is similar to the previous part. It is symmetric across the $x$ and $y$ axes due to the absolute values.

The points of intersection with the axes stay the same at $(1, 0)$, $(0, 1)$ and we also have points $(-1, 0)$ and $(0, -1)$. The curve will appear in all four quadrants, connecting these intercepts symmetrically.

To resolve the forces acting on the car at point $P$, we split them into vertical and horizontal components.

The forces include:

• Vertically: the normal force $N$ and the weight $mg$, giving: $N = mg\cos\alpha$
• Horizontally: the lateral force $F$ and the radial component due to gravity, giving: $F = mg\sin\alpha - \frac{mg^2}{r}\cos\alpha$

Therefore, combining these results allows us to establish the relationship above.

To find $v$ where $F = 0$, we set:

$0 = mg\sin\alpha - \frac{mg^2}{r}\cos\alpha$

Rearranging gives:

$mg\sin\alpha = \frac{mg^2}{r}\cos\alpha$

Dividing by $mg$ results in:

$\sin\alpha = \frac{mg}{r}\cos\alpha$

To solve for $v$, we remember that the centripetal acceleration $a_c = \frac{v^2}{r}$.

a substitution for $v$ gives:

$v^2 = rg(\sin\alpha + \frac{g\cos\alpha}{m})$

Finally, we solve for $v$ as:

$v = \sqrt{g\cdot\sin\alpha\cdot r}$