A particle of mass M and radius of gyration K is rotating with angular acceleration `alpha`. The torque acting on the particle is

If a body of mass 'm' and radius of gyration K rotates with angular velocity omega , then the angular momentum of the body will be

A body of mass m and radius of gyration K has an angular momentum L. Then its angular velocity is

Prove that the rate of change of angular momentum is equal to torque acting on the particle

A torque tau applied to a dise of mass 2 kg and radius of gyration 15 cm produces an angular acceleration of 5 "rad"//sec^(2) . Find the value of tau .

A flywheelm of mass 150 kg and radius of gyration 3 m is rotated with a speed of 480 rpm. Find the torque required to stop it in 7 rotations.

Obtain an expressing for torque acting on a body rotating with uniform angular acceleration.

A particle is at a distance r from the axis of rotation. A given torque tau produces some angular acceleration in it. If the mass of the particle is doubled and its distance from the axis is halved, the value of torque to produce the same angular acceleration is -

Two masses are attached to a rod end to end . If torque is applied they rotate with angular acceleration alpha . If their distances are doubled and same torque is applied, then they move with angular acceleration.

Starting from rest, a particle rotates in a circle of radius R  2 m with an angular acceleration  = /4 rad/s2.The magnitude of average velocity of the particle over the time it rotates quarter circle is: