A block of mass 'm' is released on the top of a frictionless incline as shown in the figure. The time period of the oscillation of the block is

The time period of oscillation of the block as shown in figure is

A system is shown in the figure. The force The time period for small oscillations of the two blocks will be

Two blocks each of mass M are resting on a frictionless inclined plane as shown in fig then:

A block of mass m is placed on the top of another block of mass M as shown in the figure. The coefficient of friction between them is mu . The maximum acceleration with which the block M may move so that m also moves along with it is

A block of 10 kg mass is placed on a rough inclined surface as shown in figure. The acceleration of the block will be

A block of mass m is released from a height R on the frictionless incline as shown. The incline leads to a circle of radius R/2. The maximum height attained by the block is

A block of mass m is released from a wedge of mass m as shown in figure . Find the time taken by the block to reach the end of the wedge.

A block of mass m is released from the top of a wedge of mass M as shown in figure. Find the displacement of wedges on the horizontal ground when the block reaches the bottom of the wedges. Neglect friction everywhere.

A block of mass 3kg is at rest on a rough inclined plan as shown in the Figure. The magnitude of net force exerted by the surface on the block will be

Two blocks are connected by a cord passing over a small frictionless pulley and resting on frictionless planes as shown in the figure. The acceleration of the blocks is :