In the system shown, the initial acceleration of the wedge of mass 5M is (there is no friction anywhere)

The acceleration of system over the wedge as shown in the figure is

A block of mass m is kept on a wedge of mass M . Initially the system is held. At certain time the system is released and the wedge is observed to move with acceleration A on inclined surface as shown. There is no friction anywhere. The acceleration of block (m) with respect to wedge (M) will be. .

A block of mass M_(1) is attached with a spring constant k . The whole arrangement is placed on a vechile as shown in the figure. If the vehicle starts moving towards right with an acceleration a (there is no friction anywhere), then : .

The coefficient of friction between the block A of mass m and the triangular wedge B of mass M is mu . There in no friction between the wedge and the plane if the system (block A+ wedge B) is released so that there is no stiding between A and B find the inclination theta

For the arrangement shown in figure when the system is released, find the acceleration of wedge. Pulley and string are ideal and friction is absent.

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

In the arrangement shown in fig. the block of mass m=2kg lies on the wedge of mass M=8kg . The initial acceleration of the wedge, if the surfaces are smooth, is

A cube of mass m is placed on top of a wedge of mass 2m, as shown in figure. There is no friction between the cube and the wedge. The minimum co - efficient of friction between the wedge and the horizontal surface, so that the wedge does not move is

A block of mass m slides down a wedge of mass M as shown . The whole system is at rest , when the height of the block is h above the ground. The wedge surface is smooth and gradually flattens. There is no friction between wedge and ground. If there is no friction any where, the speed of the wedge, as the block leaves the wedge is :