Find the mass m in the figure for the system to be at rest

In the system in the figure m_(1)gtm_(2) system is held at rest by thread BC . Just after the thread BC is burnt:

Consider the situation as shown in the figure. The boy of mass M holds the light rope and the system is at rest. If m is mass of the box, find the force exerted by the boy on the rope and contact force beteween the boy and the box.

A smooth block of mass m is held stationary on a smooth wedge of mass M and inclination theta as shown in figure .If the system is released from rest , then the normal reaction between the block and the wedge is

A system of two identical rods (L-shaped) of mass m and length l are resting on a peg P as shown in the figure. If the system is displaced in its plane by a small angle theta ,find the period of oscillations:

Two uniform thin rods each of length L and mass m are joined as shown in the figure. Find the distance of centre of mass the system from point O

Two blocks of masses 2m and m are connected by a light string going over a pulley of mass 2m and radius R as shown in the figure. The system is released from rest. Find the angular momentum of system when the mass 2m has descended through a height h . Assume no slipping.

In the arrangement shown in figure what should be the mass of block A , so that the system remains at rest ? Neglect friction and mass of string.

Two masses m and M are attached to the strings as shown in the figure. If the system is in equilibrium, then

Two masses m and M are attached to the strings as shown in the figure. If the system is in equilibruim, then

Consider a situation as shown in the figure. The system is released from rest. When the block of mass m has falled a distance L , its speed becomes (sqrt(gL))/(3) . Find the friction coefficient mu .