The function $f(x) = ext{sin} x + ext{cos} x - x$ has a zero near $x = 1.2$ - HSC - SSCE Mathematics Extension 1 - Question 3 - 2001 - Paper 1

Using the properties of angles formed by tangents and secants, when the tangent PA meets the chord AB, we know that:

$\angle ZAB = \angle AOB$

Thus, substituting the earlier result, we have:

$\angle ZAB = 2\theta.$

The relationship holds because the angle formed at the tangent point to the chord equals the angle subtended at the circumference.

From the above, since $\angle ZAB = 2\theta$ and we also have established that $O$ lies on $C_2$, we can use properties of tangents. Since line PA is tangent to circle $C_1$, at A, we can apply the tangent-radius theorem, which states that the tangent at any point is perpendicular to the radius at that point. Thus, with the angles being equal:

$\Rightarrow PA = BA$

indicates that triangles $PAB$ and $OAB$ are congruent, thereby confirming that the lengths PA and BA are equal.

To establish the required identity, recall:

$\text{sin}(3\theta) = \text{sin}(\theta + 2\theta)$

Using the sum of angles formula:

$= \text{sin} \theta \cdot \text{cos}(2\theta) + \text{cos} \theta \cdot \text{sin}(2\theta)$

Now substituting:

$\text{sin}(2\theta) = 2\text{sin} \theta \cdot \text{cos} \theta$ and $\text{cos}(2\theta) = 1 - 2\text{sin}^2 \theta$,

we can rewrite the original expression as:

$\text{sin}(3\theta) = \text{sin} \theta (1 - 2\text{sin}^2 \theta) + \text{cos} \theta (2\text{sin} \theta \cdot \text{cos} \theta)$

After simplification, this leads to:

$= 3 \text{sin} \theta - 4\text{sin}^3 \theta,$

which confirms the identity.

Starting from the identity proved earlier:

$3\text{sin} \theta - 4\text{sin}^3 \theta = 2\text{sin} \theta$

Rearranging gives:

$4\text{sin}^3 \theta - \text{sin} \theta = 0$

Factoring out $\text{sin} \theta$ yields:

$\text{sin} \theta (4\text{sin}^2 \theta - 1) = 0$

Setting each factor to zero, we find:

1. For $\text{sin} \theta = 0$, solutions are: $\theta = 0, \pi, 2\pi$

2. For $4\text{sin}^2 \theta - 1 = 0$: $\text{sin}^2 \theta = \frac{1}{4} \Rightarrow \text{sin} \theta = \frac{1}{2} \text{ or } -\frac{1}{2}$ Leading to: $\theta = \frac{\pi}{6}, \frac{5\pi}{6}$

Thus the complete set of solutions is:

$\theta = 0, \frac{\pi}{6}, \frac{5\pi}{6}, \pi, 2\pi$

Summarizing, the solutions for $0 \leq \theta < 2\pi$ are:

$\theta = 0, \frac{\pi}{6}, \frac{5\pi}{6}, \pi$