A solid cylinder of radius 4 cm and mass 250 g rolls down an inclined plane (1 in 10). Calculate the acceleration and the total energy of the cylinder after 5 s.

A solid cylinder of radius 5 cm and mass 0.5 kg rolls down an inclined plane (1 in 10). Calculate the acceleration and total energy of the cylinder after 10 S.

Calculate the acceleration of a solid cylinder of radius 2 cm and mass 150 g which is rolling down an incline plane of 1 in 20 Also find the total energy of cylinder after 10 s.

A solid cylinder of mass 500 g and radius 10 cm rolls down an inclined plane of inclination 1 in 10. Calculate its acceleration and total energy after 6 s.

A cylinder of mass m and radius R rolls down an inclined plane of inclination theta . Calculate the linear acceleration of the axis of cylinder.

A cylinder of mass m and radius R rolls down an inclined plane of inclination theta . Calculate the linear acceleration of the axis of cylinder.

Assertion: A solid cylinder of mass m and radius r rolls down an inclined plane of height H. The rotational kinetic energy of the cylinder when it reaches the bottom of the plane is mgH/3. Reason: The total energy of the cylinder remains constant throughout its motion.

A solid cylinder, of mass 2 kg and radius 0.1 m, rolls down an inclined plane of height 3m. Calculate its rotational energy when it reaches the foot of the plane.

A solid cylinder of mass 8 kg is rolling perfectly down an inclined plane of inclination 30. Calculate the force of friction between the cylinder and inclined plane and acceleration of the cylinder down the inclined plane.

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

A cylinder rolls down an inclined plane of inclination 30^@ , the acceleration of cylinder is