The points 'A' and 'B' of a disc are pulled with velocity 'V' as shown in the diagram. Then the velocity of centre 'C' of disc (here the points A, B, C lie on same diameter) will be
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Due to slippoing points A and B on the rim of the disk have the velocities shown. Determine the velocities of the centre point C and point F at this instant.

A particle is given velocity v_0 at point A as shown in the figure. Find the speed of particle at point B,C and D

A disc of radius R has linear velocity v and angular velocity omega as shown in the figure. Given upsilon=romega find velocity of point A, B, C and D on the disc.

A disc is rolling on an inclined plane without slipping. The velocity of centre of mass is V . These other point on the disc lie on a circular are having same speed as centre of mass. When a disc is rolling on an inclined plane. The magnitude of velocities of all the point from the contact point is same, having distance equal to radius r .

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 circular disc of radius R is rotating about its axis O with a uniform angular velocity omega"rad s"^(-1) as shown in the figure. The magnitude of the relative velocity of point A relative to point B on the disc is

A disc of mass m and radius R, is placed on a smooth text service fixed surface . Point A is the geometrical centre of the disc while point B is the centre of mass of the disc . The moment of inertia of the dics about an axis through its centre of mass and perpendicular to the plane of the figure is I .A constant force F is applied to the top of the disc . The acceleration of the centre A of the disc at the instant B is below A (on the same vertical line ) will be :