A particle P of mass m moves with constant angular velocity ω on a circle of radius r. Its position at time t is given by: $x = r \cos \theta$ y = r \sin \theta$, where $ \theta = \omega t $. (i) Show that there is an inward radial force of magnitude $mr\omega^2$ acting on P. (ii) A telecommunications satellite, of mass m, orbits Earth with constant angular velocity ω at a distance r from the centre of Earth. The gravitational force exerted by Earth on the satellite is $\frac{Am}{r^2}$, where A is a constant. By considering all other forces on the satellite to be negligible, show that $r = \sqrt{\frac{A}{\omega^2}}$. (b) (i) Derive the equation of the tangent to the hyperbola $\frac{x^2}{a^2} - \frac{y^2}{b^2} = 1$ at the point P $(a \sec \theta, b \tan \theta)$. (ii) Show that the tangent intersects the asymptotes of the hyperbola at the points $A \left( a \cos \theta, b \cos \theta \right)$ and $B \left( \frac{-a \cos \theta}{1 + \sin \theta}, \frac{b \cos \theta}{1 - \sin \theta} \right)$. (iii) Prove that the area of the triangle OAB is $\alpha b$. (c) A hall has n doors. Suppose that n people each choose any door at random to enter the hall. (i) In how many ways can this be done? (ii) What is the probability that at least one door will not be chosen by any of the people?

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A particle P of mass m moves with constant angular velocity ω on a circle of radius r - HSC - SSCE Mathematics Extension 2 - Question 4 - 2003 - Paper 1

Question 4

A particle P of mass m moves with constant angular velocity ω on a circle of radius r. Its position at time t is given by: $x = r \cos \theta$ y = r \sin \theta$, ... show full transcript

Worked Solution & Example Answer:A particle P of mass m moves with constant angular velocity ω on a circle of radius r - HSC - SSCE Mathematics Extension 2 - Question 4 - 2003 - Paper 1

Step 1

(i) Show that there is an inward radial force of magnitude $mr\omega^2$ acting on P.

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Answer

To find the inward radial force acting on a particle moving in a circular path, we start with the definition of centripetal acceleration. The centripetal acceleration ( $a_c$ ) is given by the formula:

$a_c = r \omega^2$

The radial force ( $F_r$ ) can then be derived from Newton's second law, $F = ma$ , where $m$ is the mass of the particle:

$F_r = m a_c = m (r \omega^2)$

Thus, the inward radial force is:

$F_r = mr\omega^2$

Step 2

(ii) Show that $r = \sqrt{\frac{A}{\omega^2}}$.

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Answer

The gravitational force acting on the satellite is given by:

$F_g = \frac{Am}{r^2}$

This force must equal the centripetal force required to keep the satellite in circular motion:

$F_c = m \omega^2 r$

Setting these forces equal provides:

$\frac{Am}{r^2} = m \omega^2 r$

By canceling $m$ from both sides and rearranging, we have:

$A = \omega^2 r^3$

From here, solving for r yields:

$r^3 = \frac{A}{\omega^2}$

Thus,

$r = \sqrt[3]{\frac{A}{\omega^2}}$

Step 3

(i) Derive the equation of the tangent to the hyperbola at the point P $(a \sec \theta, b \tan \theta)$.

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Answer

To derive the equation of the tangent to the hyperbola given by:

$\frac{x^2}{a^2} - \frac{y^2}{b^2} = 1$

at point P $(a \sec \theta, b \tan \theta)$ , we utilize the point-slope form of the tangent line to a hyperbola. The slope ( $m$ ) of the tangent at P can be found using implicit differentiation:

Differentiate both sides:
- The derivative of left-hand side with respect to x gives:
$\frac{2x}{a^2} - \frac{2y}{b^2} \frac{dy}{dx} = 0$
- Solving for $\frac{dy}{dx}$ gives:
$\frac{dy}{dx} = \frac{y \cdot a^2}{x \cdot b^2}$
Substitute point P into slope formula to find the slope at that point.

Once the slope is determined, use the point-slope form:

$y - b \tan \theta = m (x - a \sec \theta)$

Step 4

(ii) Show that the tangent intersects the asymptotes of the hyperbola at the points $A \left( a \cos \theta, b \cos \theta \right)$ and $B \left( \frac{-a \cos \theta}{1 + \sin \theta}, \frac{b \cos \theta}{1 - \sin \theta} \right)$.

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Answer

To show where the tangent intersects the asymptotes of the hyperbola:

The asymptotes of the hyperbola are:
- $y = \pm \frac{b}{a} x$
Substitute the equation of the tangent into the equation of the asymptotes to find the points of intersection.

Using the derived tangent equation from part (i), set it equal to the asymptotes' equations to isolate x and y coordinates leading to the points A and B as outlined.

Step 5

(iii) Prove that the area of the triangle OAB is $\alpha b$.

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Answer

To find the area of triangle OAB, we can use the formula for the area of a triangle based on coordinates:

$\text{Area} = \frac{1}{2} | x_1(y_2 - y_3) + x_2(y_3 - y_1) + x_3(y_1 - y_2) |$

Let O be the origin (0,0), and A and B be the coordinates as derived previously.
Substitute these coordinates into the area formula.
After performing the calculations and simplifying, it can be shown:

$\text{Area} = \alpha b$

Step 6

(i) In how many ways can this be done?

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When n people choose a door to enter the hall, and each person can choose independently, the total number of ways this can be done is calculated as follows:

Each person has n choices (doors). Thus, the total combinations can be expressed as:

$n^n$

Step 7

(ii) What is the probability that at least one door will not be chosen by any of the people?

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Answer

To find the probability that at least one door will not be chosen by any of the n people, it is often easier to use the complement rule:

Calculate the probability that all doors are chosen by at least one person, denoted as $P(all)$ .
The probability that at least one door is not chosen is then:

$P(at least \, one \, not \, chosen) = 1 - P(all)$

$P(all)$ can be derived using counting principles and depends on combinations calculated previously.

A particle P of mass m moves with constant angular velocity ω on a circle of radius r - HSC - SSCE Mathematics Extension 2 - Question 4 - 2003 - Paper 1

Worked Solution & Example Answer:A particle P of mass m moves with constant angular velocity ω on a circle of radius r - HSC - SSCE Mathematics Extension 2 - Question 4 - 2003 - Paper 1

(i) Show that there is an inward radial force of magnitude $mr\omega^2$ acting on P.

(ii) Show that $r = \sqrt{\frac{A}{\omega^2}}$.

(i) Derive the equation of the tangent to the hyperbola at the point P $(a \sec \theta, b \tan \theta)$.

(ii) Show that the tangent intersects the asymptotes of the hyperbola at the points $A \left( a \cos \theta, b \cos \theta \right)$ and $B \left( \frac{-a \cos \theta}{1 + \sin \theta}, \frac{b \cos \theta}{1 - \sin \theta} \right)$.

(iii) Prove that the area of the triangle OAB is $\alpha b$.

(i) In how many ways can this be done?

(ii) What is the probability that at least one door will not be chosen by any of the people?

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