A uniform thin spherical shell of mass m and radius R rolls down without slipping over an inclined plane of angle `theta` with the horizontal. The ratio of rotational kinetic energy to the total kinetic energy of the shell will be

A drum of radius R and mass M, rolls down without slipping along an inclined plane of angle theta . The frictional force-

A solid cylinder of mass M and radius R rolls without slipping down an inclined plane making an angle 6 with the horizontal. Then its acceleration is.

A uniform sphere of mass m and radius R rolls without slipping down an inclined plane set at an angle theta to the horizontal. Find ( a ) the friction coefficient at which slipping is absent, ( b ) the kinetic energy of the sphere t seconds after the beginning of motion.

A spherical shell of mass m and radius R is rolling up without slipping on a rough inclined plane as shown in the figure. The direction of static friction acting on the shell is

A ring is rolling without slipping. The ratio of translational kinetic energy to rotational kinetic energy is

A solid spherical ball rolls on a table. Ratio of its rotational kinetic energy to total kinetic energy is

A circular disc rolls down an inclined plane . The ratio of rotational kinetic energy to total kinetic energy is

A round uniform body of radius R , mass M and moment of inertia 'I' rolls down (without slipping) and inclined plane making an angle theta with the horizontal. Then its acceleration is.

A disc is rolling without slipping. The ratio of its rotational kinetic energy and translational kinetic energy would be -

A solid sphere is rolling without slipping on a horizontal plane. The ratio of its rotational kinetic energy and translational kinetic energy is