SSCE HSC Mathematics Extension 1 Projectile motion: Two particles are fired simultan

Question

Two particles are fired simultaneously from the ground at time $t = 0$.  
Particle 1 is projected from the origin at an angle, $0 < 	heta < \frac{\pi}{2}$, with an initial velocity $V$.  
Particle 2 is projected vertically upward from the point $A$, at a distance $a$ to the right of the origin, also with an initial velocity $V$.

It can be shown that while both particles are in flight, Particle 1 has equations of motion:  
$$x = Vt \cos 	heta$$  
$$y = Vt \sin 	heta - \frac{1}{2}gt^2$$

and Particle 2 has equations of motion:  
$$\dot{x} = a$$  
$$y = Vt - \frac{1}{2}gt^2.$$

Do NOT prove these equations of motion.  
Let $L$ be the distance between the particles at time $t$.

(i) Show that, while both particles are in flight,  $L^2 = 2V^2t^2(1 - \sin 	heta) - 2aVt \cos 	heta + a^2$.

(ii) An observer notices that the distance between the particles in flight first decreases, then increases.  
Show that the distance between the particles in flight is smallest when  $t = \frac{a \cos 	heta}{2V(1 - \sin 	heta)}$ and that this smallest distance is $\frac{a}{2} \sqrt{1 - \sin 	heta}$.

(iii) Show that the smallest distance between the two particles in flight occurs while Particle 1 is ascending if $V > \frac{a \cos 	heta}{\sqrt{2}\sin 	heta(1 - \sin 	heta)}$.

Two particles are fired simultaneously from the ground at time $t = 0$ - HSC - SSCE Mathematics Extension 1 - Question 6 - 2006 - Paper 1

Worked Solution & Example Answer:Two particles are fired simultaneously from the ground at time $t = 0$ - HSC - SSCE Mathematics Extension 1 - Question 6 - 2006 - Paper 1

Show that, while both particles are in flight, $L^2 = 2V^2t^2(1 - \sin \theta) - 2aVt \cos \theta + a^2$.

Show that the distance between the particles in flight is smallest when $t = \frac{a \cos \theta}{2V(1 - \sin \theta)}$ and that this smallest distance is $\frac{a}{2} \sqrt{1 - \sin \theta}$.

Show that the smallest distance between the two particles in flight occurs while Particle 1 is ascending if $V > \frac{a \cos \theta}{\sqrt{2}\sin \theta(1 - \sin \theta)}$.

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