Given that a small ball is fastened to a long rubber band and twirled
around it such a way that the ball moves in an elliptical path
given by the equation
[tex]r(t) = i\, 4b \cos(\omega t) + j\, 3b \sin(\omega t)[/tex],
where b
and [tex]w[/tex] are positive constants.
a) The velocity of the ball v as a function of time t is given by
[tex]v=r'(t) = -i\, 4b\omega \sin(\omega t) + j\, 3b\omega \cos(\omega t)[/tex].
b) The speed of the ball v = |v| as a function of t is given by
[tex]|v|=|r'(t)| = \sqrt{\left(4b\omega \sin(\omega t)\right)^2+\left(3b\omega \cos(\omega t)\right)^2} \\ \\ = \sqrt{16b^2\omega^2\sin^2(\omega t)+9b^2\omega^2\cos^2(\omega t)} [/tex].
c) The speed v at t = 0 at which time the ball is at its
maximum distance from the origin is given by
[tex]v=\sqrt{16b^2\omega^2\sin^2(\omega (0))+9b^2\omega^2\cos^2(\omega (0))} \\ \\ =\sqrt{16b^2\omega^2\sin^2(0)+9b^2\omega^2\cos^2(0)}=\sqrt{16b^2\omega^2(0)+9b^2\omega^2(1)} \\ \\ = \sqrt{9b^2\omega^2} =\bold{3b\omega}[/tex].
d) The speed v at [tex]t = \frac{\pi}{2\omega}[/tex] at which time the ball is at
its minimum distance from the origin is given by
[tex]v=\sqrt{16b^2\omega^2\sin^2(\omega ( \frac{\pi}{2\omega} ))+9b^2\omega^2\cos^2(\omega ( \frac{\pi}{2\omega} ))} \\ \\ =\sqrt{16b^2\omega^2\sin^2( \frac{\pi}{2} )+9b^2\omega^2\cos^2( \frac{\pi}{2} )}=\sqrt{16b^2\omega^2(1)+9b^2\omega^2(0)} \\ \\ = \sqrt{16b^2\omega^2} =\bold{4b\omega}[/tex].
e) The acceleration of the ball, a, as a function of t is given by
[tex]a=r''(t) = -i\, 4b\omega^2 \cos(\omega t) - j\, 3b\omega^2 \sin(\omega t)[/tex].
f) The magnitude of the acceleration of the ball
[tex]|a|=|r''(t)| = \sqrt{\left(4b\omega^2 \cos(\omega t)\right)^2+\left(3b\omega^2 \sin(\omega t)\right)^2} \\ \\ = \sqrt{16b^2\omega^4\cos^2(\omega t)+9b^2\omega^4\sin(\omega t)} [/tex].
