A body is released from the top of an inclined plane of inclination `(theta)`. fIt reaches the bottom with velocity (v), If keeping the length same the angle of inclination is doubled, what will be the velocity of the body on reaching the ground:-

A body is released from the top of a smooth inclined plane of inclination theta . It reaches the bottom with velocity v . If the angle of inclina-tion is doubled for the same length of the plane, what will be the velocity of the body on reach ing the ground .

A block is kept on an inclined plane of inclination theta of length l. the velocity of particle at the bottom of inclined is (the coefficient of friciton is mu )

A solid cylinder rolls up an inclined plane of inclination theta with an initial velocity v . How far does the cylinder go up the plane ?

A block is kept on a inclined plane of inclination theta of length l. The velocity of particle at the bottom of inclined is (the coefficient of friction is mu

A body is projected up along an inclined plane from the bottom with speed V_(1) . If it reaches the bottom of the plane with a velocity V_(2) , find (v_(1)//v_(2)) if theta is the angle of inclination with the horizontal and mu be the coefficient of.

A sphere rolls down on an inclined plane of inclination theta . What is the acceleration as the sphere reaches bottom?

A hollow sphere is released from top of an inclined plane of inclination 30º and length of inclined plane is /. If sphere rolls without slipping then its speed at bottom is

A sphere rolls down on an inclied plane of inclination theta . What is the acceleration as the sphere reaches bottom ?

A block moves down a smooth inclined plane of inclination theta . Its velocity on reaching the bottom is v. If it slides down a rough inclined plane of some inclination, its velocity on reaching the bottom is v/n, where n is a number greater than 0. The coefficient of friction is given by -

A body of mass m slides down an incline and reaches the bottom with a velocity v . If the same mass were in the form of a ring which rolls down this incline, the velocity of the ring at the bottom would have been