A circular disc first rolls without slipping and then slides without rolling down the same inclined plane. The ratio of velocities of the disc at the bottom of the plane in both the cases repectively is

A solid cylinder and a solid sphere roll down on the same inclined plane. Then ratio of their acclerations is

A cylinder rolls without slipping down an inclined plane, the number of degrees of freedom it has, is

'A' solid sphere and solid disc having the same mass and radius roll down on the same inclined plane. What is the ratio of their accelerations ?

A thin hollow cylinder open at both ends slides without rotating and then rolls without slipping with the same speed. The ratio of the kinetic energies in the two cases is

A solid sphere rolls without slipping down a 30^@ inclined plane. If g=10ms^-2 then the acceleration of the rolling sphere is

A cylindrical ring is rolling without slipping. The ratio of rotational and translational kinetic energies is

A circular disc rolls down on an inclined plane. The fraction of its total rolling energy associated with its rotational energy is,

A solid cylinder at rest at top of an inclined plane of height 2.7 m rolls down without slipping. If the same cylinder has to slide down a frictionless inclined plane and acquires the same velocity as that acquired by centre of mass of rolling cylinder at the bottom of the incline, what should be the height of the inclined plane?

A circular disc of mass 0.41 kg and radius 10 m rolls without slipping with a velocity of 2 m/s. The total kinetic energy of disc is

A solid sphere rolls up a plane inclined at an angle of 45^@ . If the linear velocity of its centre of mass of the bottom of the plane is 5ms^-1 , find how far the sphere travels up the plane.