Angular acceleration of a body of mass 50 kg under the action of a torque of magnitude 500 Nm is `25 rad//s^2` . Then radius of gyration of the body about its axis of rotation is nearly equal to

Angular acceleration of a body of mass 50 kg under the action of a torque of magnitude 500 Nm is 25 rad s^2 . Find the radius of gyration of the body about its axis of rotation.

A body of mass M is rotating about an axis with angular velocity omega . If k is radius of gyration of the body about the given axis, its angular momentum is

A torque of 400 Nm acting on a body of mass 40 kg produces an angular acceleration of 20 rad/s^2 . Calculate the moment of inertia and radius of gyration of the body.

The rotational kinetic energy of a body is E. In the absence of external torque, the mass of the body is halved and its radius of gyration is doubled. Its rotational kinetic energy is

The angular velocity of the body changes from omega_1 to omega_2 without applying torque but by changing its M.I. The ratio of initial radius of gyration to final radius of gyration is

A solid sphere has a radius R . If the radius of gyration of this sphere about its diameter is sqrt(2//5) R , show that the radius of gyration about the tangential axis of rotation is sqrt(7//5) R

Calculate the torque necessary to produce an angular acceleration of 25 rad/s^2 in fly wheel of mass 50 kg and radius of gyration 50 cm about its axis.

A body of mass 'm' and radius of gyration 'K' is rotating with angular acceleration a. Then the torque acting on the body is

A body of mass 2 kg is rotating with angular speed 2pi rad s^-1 in a circular path of radius 1m. The centripetal force acting on the body is.

A body of mass10 kg ismoving in a circle of radius 1 m with an angular velocity of 2 rad/s. The centripetal force is