A small bead of mass m is attached to one end of a light string of length R - HSC - SSCE Mathematics Extension 2 - Question 5 - 2011 - Paper 1

To isolate N, we can combine the two equations derived earlier. We can substitute for F from one equation into the other:

From the horizontal equation: $F = N \sin{\theta} + mω²r$

Substituting this into the vertical forces equation:

$(N \sin{\theta} + mω²r) \cos{\theta} + N \cos{\theta} = mg$

Rearranging will give: $N(\sin{\theta} \cos{\theta} + \cos{\theta}) = mg - mω²r$

Simplifying this expression gives us:

$N = \frac{mg - mω²r}{\sin{\theta} \cos{\theta} + \cos{\theta}}$

To determine the condition under which the bead remains in contact with the sphere, we analyze the derived expression for N. For N to be non-negative (indicating contact), we can rewrite the equation:

$N = \frac{1}{2} m g \sec{θ} - \frac{1}{2} m \frac{ω²}{g} r \csc{θ} ≥ 0$

This leads to: $g \sec{θ} ≥ \frac{ω²}{g} r \csc{θ}$

From here, we simplify further to show that: $ω² ≤ \frac{g^2}{h}$

Thus, if the condition $ω ≤ \frac{g}{h}$ holds, the bead will remain in contact with the sphere.

We first combine the fractions on the left by obtaining a common denominator:

$\frac{p(1 + q)(1 + r) + q(1 + p)(1 + r) + r(1 + p)(1 + q)}{(1 + p)(1 + q)(1 + r)}$

Now, simplifying the numerator will yield a polynomial in p, q, r that reflects their positivity since p, q, and r are positive reals. Therefore, we can conclude that the entire expression remains non-negative.

The reflection property of the ellipse states that the angle of incidence equals the angle of reflection. Since the line l is tangent at point P, the angle at which the light rays toward S reflect off the tangent will cause them to intersect at Q. Thus, we can deduce that:

$SQ = RQ$ This derives from the properties of the tangent and the reflective angles.

By definition, the foci S and S' of an ellipse are located at a distance of c from the center O, where:

$c = \sqrt{a^2 - b^2}$

The distance between the foci S and S', which is $2c = S'S$, gives us the resulting length along the major axis, satisfying that:

$S′R = 2a$

Since Q is the point of intersection derived from the reflection properties and the ellipse's tangent, we can analyze the coordinates of Q that lies along the extension of the major axis. Given the geometric properties laid out, we can show that: $x^2 + y^2 = a^2$ This confirms that point Q lies indeed on the specified circle.