A solid body rotates about a stationary axis so that its angular velocity depends on the rotation angle  as   = 0 – k , where    0 and k are positive constants. At the moment t = 0, the angle  = 0. Find the time dependence of rotation angle -

A solid body rotates about a stationary axis so that its angular velocity depends on the rotation angle varphi as omega=omega_0-avarphi , where omega_0 and a are positive constants. At the moment t=0 the angle varphi=0 . Find the time dependence of (a) the rotation angle, (b) the angular velocity.

A solid body rotates about a stationary axis so that its angular velocity depends on the rotational angle (phi) as omega= omega_(0) - kphi where omega_(0) and K are positive constant, At the moment t=0, phi= 0, the time depen dence of rotation angle is

A solid body rotates about a stationary axis, so that its angular velocity depends on the rotational angle phi as omega=omega_(0)-kphi where omega_(0) and K are positive constants. At the moment t=0,phi=0 Find the dependence of rotation angle.

A solid body rotest about a stationary axis, so that its angular velocity depends on the rotational angle phi as omega=omega_(0)-kphi where omega_(0) and K are postitive constatns. At the moment t=0,phi=0 Find the dependence of rotaions angle.

A solid body rotates about a stationary axis so that its angular velocity depends upon the rotation angle phi as omega - omega_(0) = aphi , where a and omega_(0) are positive constants. Initially that is at t = 0 , phi = 0 .

A rigid body rotates about a fixed axis with variable angular velocity equal to (a - bt) at time t where a and b are constants. The angle through which it rotates before it comes to rest is

A rigid body rotates about a fixed axis with variable angular velocity equal to (a - bt) at time t where a and b are constants. The angle through which it rotates before it comes to rest is

A solid body rotates about a stationary axis so that the rotation angle theta varies with time as theta=6t-2t^(3) radian. Find (a) the angular acceleration at the moment when the body stops and (b) the average value of angular velocity and angular acceleration averaged over the time interval between t=0 and the complete stop.