A block of mass `m` rests on a stationary wedge of mass M. The wedge can slide freely on a smooth horizontal surface as shown in figure. If the block starts from rest

A small block of mass m is placed at rest on the top of a smooth wedge of mass M, which in turn is placed at rest on a smooth horizontal surface as shown in figure. If h be the height of wedge and theta is the inclination, then the distance moved by the wedge as the block reaches the foot of the wedge is

A block of mass m is placed at rest on a smooth wedge of mass M placed at rest on a smooth horizontal surface. As the system is released

A block of mass m lies on a wedge of mass M. The wedge in turn lies on smooth horizontal surface. Friction is absent everywhere. The wedge block system is released from rest. All situations given in Table-1 are tol be estimated in the duration the block undergoes a vertical displacement 'h' starting from rest. Match the statement in Table-1 with the results in Table-2 ltbgt

A particle of mass m is placed at rest on the top of a smooth wedge of mass M, which in turn is placed at rest on a smooth horizontal surface as shown in figure. Then the distance moved by the wedge as the particle reaches the foot of the wedge is :

A block B of mass 0.6kg slides down the smooth face PR of a wedge A of mass 1.7kg which can move freely on a smooth horizontal surface. The inclination of the face PR to the horizontal is 45^(@) . Then :

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 block of mass M is tied to one end of a massless rope. The other end of the rope is in the hands of a man of mass 2M as shown in Fig. The block and the man art resting on a rough wedge of mass M . The whole system is resting on a smooth horizontal surface. The man starts walking towards right while holding the rope in his hands. Pulley is massless and frictionless. Find the displacement of the wedge when the block meets the pulley. Assume wedge is sufficiently long so that man does not fall down.

A block of mass m slides over a smooth wedge of mass M which is placed over a rough horizontal surface . The centre of mass of the system will move towards left Here mu = coefficient of friction between the wedge and the ground .

A small ball ( uniform solid sphere ) of mass m is released from the top of a wedge of the same mass m . The wedge is free to move on a smooth horizontal surface. The ball rolld without sliding on the wedge. The required height of the wedge are mentioned in the figure. The total kinetic energy of the ball just before it falls on the ground

A small block of mass m rests on a smooth wedge of angle theta . With what horizontal accelaration a should the wedge be pulled, as shown in fig, so that the block falls freely?