A block of A is released from rest from the top of wedge block of height h shown in figure-4.55. If velocity of block when it reaches the bottom of inclive is `v_(0)`, find the time os sliding.

A block is released from the top of the smooth inclined plane of height h . Find the speed of the block as it reaches the bottom of the plane.

A block of mass 4kg is released from the top of a rough inclines plane of height 10 m . If velocity of the block is 10 m/s at the bottom of the inclined then work done by the friction force on the block will be

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 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 slides down along the surface of the bowl from the rim to the bottom as shown in fig. The velocity of the block at the bottom will be-

The block shown in figure is released from rest. Find out the speed of the block when the spring is compressed by 1 m

A block of mass m is released from the top of a mooth inclined plane of height h its speed at the bottom of the plane is proportion to

A block released from rest from the tope of a smooth inclined plane of angle of inclination theta_(1) = 30^(@) reaches the bottom in time t_(1) . The same block, released from rest from the top of another smooth inclined plane of angle of inclination theta_(2) = 45^(@) reaches the bottom in time t_(2) . Time t_(1) and t_(2) are related as ( Assume that the initial heights of blocks in the two cases are equal ).

A block of mass m is released from rest onto a spring. A having stiffness k_A=mg//2h as shown in figure. If the block compresses spring B through a distance h, find the: a. stiffness of the spring B b. equilibrium position of the block c. maximum velocity of the block d. maximum acceleration of the block