A thin wallet hollow cylinder is rolling down an incline , without slipping. At any instant , the ratio " Rotational K.E : Translational K.E:Total K.E." is

A thin walled hollow cylinder is rolling down an incline, without slipping. At any instant, the ratio "Rotational K.E.: Translational K.E.: Total K.E." is:

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

A sphere of moment of inertia I and mass 'm' rolls down on an inclined plane without slipping. Its K.E. of rolling is.

A sphere of moment of inertia I and mass 'm' rolls down on an inclined plane without slipping. Its K.E. of rolling is

A ring rotates without slipping on a horizontal smooth surface, the ratio of translational energy to the total energy of the ring is

The M.I. of a solid cylinder about its axis is I. It is allowed to roll down an inclined plane without slipping. If its angular velocity at the bottom be omega , then kinetic energy of rolling cylinder will be

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

The radius of a wheel is R and its radius of gyration about an axis passing through its centre and perpendicular to its plane is k. If the wheel is rolling without slipping , the ratio of its rotational kinectic energy to its translational kinectic energy is

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 cylinder of mass 0.1 kg having radius 0.2 m rolls down an inclined plane of height 0.6 m without slipping. The linear velocity of the cylinder at the bottom of the inclined plane is