A rod 'A' constrained to move in vertical direction rests on a wedge B, as shown in the Fig. Find the accelerations of rod A and wedge B instantaneously after system is released from rest, neglecting friction at all the contact surfaces.

Find the acceleration of the hemisphere immediately after the system is released from rest. There is no friction anywhere.

A rod of mass m is supported on a wedge of mass M shown in fig. Find the accelerations of rod a and wedge A in the arrangment. The friction between all contact surfaces in negligible.

Two blocks A and B of equal masses are attached to a string passing over a smooth pulley fixed to a wedge as shown in figure. Find the magnitude of acceleration of centre of mass of the two blocks when they are released from rest. Neglect friction.

A block of mass m is placed on the inclined sufrace of a wedge as shown in fig. Calculate the acceleration of the wedge and the block when the block is released. Assume all surfaces are frictionless.

Find the acceleration of rod A and wedge B in the arrangement shown in fig if the ratio of the mass of wedge to that of the rod equals eta and the friction between the contact surfaces are negligible.

In the figure shown , all surface are smooth . Acceleration of mass '4m' , when the system Is released from rest will be

Find the accelerations of rod A and wedge B in the arrangement shown in figure if the ratio of the mass of the wedge to that of the rod equals eta , and the friction between all contact surfaces is negligible.

A plank of mass m rests symmetrically on two wedges B and C of mass M. What is the acceleration of the plank? Neglect friction between all the contact surfaces.

In fig. mass m is being pulled on the incline of a wedge of mass M. All the surfaces are smooth. Find the acceleration of the wedge.