A ball of mass 100 g released down an inclined plane describes a circle of radius 10 cm in the vertical plane on reaching the bottom of the inclined plane . The minimum height of the incline is

A ball of 1 g released down an inclined plane describes a circle of radius 10 cm in the vertical plane on reaching the bottom. The minimum height of the inclined plane is

A ball of 1 gm released down an inclined plane describes a circle of radius 10 cm in the vertical plane on reaching the bottom . The minimum height of the inclined plane is … cm.

A disc of mass 3 kg rolls down an inclined plane of height 5 m. The translational kinetic energy of the disc on reaching the bottom of the inclined plane is

A disc of mass 3 kg rolls down an inclined plane of height 5 m. The translational kinetic energy of the disc on reaching the bottom of the inclined plane is

A ring rolls down an inclined plane and acquires a velocity v upon reaching the bottom of the inclined plane. If another body rolls down from the same height over the same inclined plane and acquires a velocity sqrtfrac{6}{5}v upon reaching the bottom of the inclined plane, then that body is

A ring rolls down an inclined plane and acquires a velocity v upon reaching the bottom of the inclined plane. If another body rolls down from the same height over the same inclined plane and acquires a velocity sqrtfrac{6}{5}v upon reaching the bottom of the inclined plane, then that body is

A mass m slides down a fixed plane inclined at an angle a to the horizontal plane after covering the entire length of the inclined plane. The height of the inclined plane is h and the coefficient of friction over both surfaces is mu .

A solid sphere of mass m rolls down an inclined plane without slipping from rest at the top of an inclined plane.The linear speed of the sphere at the bottom of the inclined plane is v .The kinetic energy of the sphere at the bottom is

The velocity of the rolling object on inclined plane at the bottom of inclined plane is

A block is released from the top of an inclined plane of inclination theta and height h. Time required to reach the foot of the inclined plane is