Problems

Two particles \(P_{1}\) and \(P_{2}\), each of mass \(m\), are joined by a light smooth inextensible string of length \(\ell.\) \(P_{1}\) lies on a table top a distance \(d\) from the edge, and \(P_{2}\) hangs over the edge of the table and is suspended a distance \(b\) above the ground. The coefficient of friction between \(P_{1}\) and the table top is \(\mu,\) and \(\mu<1\). The system is released from rest. Show that \(P_{1}\) will fall off the edge of the table if and only if \[ \mu<\frac{b}{2d-b}. \] Suppose that \(\mu>b/(2d-b)\) , so that \(P_{1}\) comes to rest on the table, and that the coefficient of restitution between \(P_{2}\) and the floor is \(e\). Show that, if \(e>1/(2\mu),\) then \(P_{1}\) comes to rest before \(P_{2}\) bounces a second time.

\(\,\)

A horizontal circular disc of radius \(a\) and centre \(O\) lies on a horizontal table and is fixed to it so that it cannot rotate. A light inextensible string of negligible thickness is wrapped round the disc and attached at its free end to a particle \(P\) of mass \(m\). When the string is all in contact with the disc, \(P\) is at \(A\). The string is unwound so that the part not in contact with the disc is taut and parallel to \(OA\). \(P\) is then at \(B\). The particle is projected along the table from \(B\) with speed \(V\) perpendicular to and away from \(OA\). In the general position, the string is tangential to the disc at \(Q\) and \(\angle AOQ=\theta.\) Show that, in the general position, the \(x\)-coordinate of \(P\) with respect to the axes shown in the figure is \(a\cos\theta+a\theta\sin\theta,\) and find \(y\)-coordinate of \(P\). Hence, or otherwise, show that the acceleration of \(P\) has components \(a\theta\dot{\theta}^{2}\) and \(a\dot{\theta}^{2}+a\theta\ddot{\theta}\) along and perpendicular to \(PQ,\) respectively. The friction force between \(P\) and the table is \(2\lambda mv^{2}/a,\) where \(v\) is the speed of \(P\) and \(\lambda\) is a constant. Show that \[ \frac{\ddot{\theta}}{\dot{\theta}}=-\left(\frac{1}{\theta}+2\lambda\theta\right)\dot{\theta} \] and find \(\dot{\theta}\) in terms of \(\theta,\lambda\) and \(a\). Find also the tension in the string when \(\theta=\pi.\)