A cycle tyre of mass M and radius R is in pure rolling over a horizontal surface. If the velocity of the centre of mass of the tyre is v, then the velocity of point P on the tyre, shown in figure is

A thin ring of mass m and radius R is in pure rolling over a horizontal surface. If v_0 is the velocity of the centre of mass of the ring, then the angular momentum of the ring about the point of contact is

If the velocity of centre of mass of a rolling body is V then velocity of highest point of that body is

A uniform circular disc of radius R is rolling on a horizontal surface. Determine the tangential velocity : the centre of mass

If V is velocity of centre of mass of a rolling body then velocity of lowest point of that body is

A uniform ring of mass m and radius R is in uniform pure rolling motion on a horizontal surface. The velocity of the centre of ring is V_(0) . The kinetic energy of the segment ABC is:

A disc rolls without slipping on a horizontal surface such that its velocity of center of the mass is v . Find the velocity of points A , B , C and D .

A uniform circular disc of mass M and radius R rolls without slipping on a horizontal surface. If the velocity of its centre is v_0 , then the total angular momentum of the disc about a fixed point P at a height (3R)//2 above the centre C .

A loop of mass M and radius R is rolling on a smooth horizontal surface with speed 'v'. It's total kinetic energy is

A uniform ring of mass m and radius R is performing pure rolling motion on a horizontal surface. The velocity of centre of the ring is V_(0) . If at the given instant the kinetic energy of the semi circular are AOB is lambda mv_(0)_(2) , then find the value of 11lambda ("take" pi=(22)/(7))

The velocity (in m/s) of centre of mass of the system as shown in the figure is :