Find the velocity of the hanging block if the velocities of the free ends of the rope are as indicated in the figure.

The velocity of the block B is:

Find the velocity of center of mass of the system shown in the figure.

A block of mass M is pulled along a horizontal frictionless surface by a rope of mass m as shown in A horizontal force F is applied to one end of the rope. Find (a) the acceleration of the rope and block (b) the force that the rope exerts on the block (c) the tension in the rope at its mid point

A uniform rope of length l and mass m lies on a smooth horizontal table with its length perpendicular to the edge of the table and a small part of the rope having over the edge. The rope starts sliding from rest under the weight of the over hanging end. The velocity of the rope when the length of the hanging part is . x

In the given figure all the surfaces are smooth. Find the time taken by the block to reach from the free end to the pulley attached to the plank. Distance between free end and pulley is l .

A rope thrown over a pulley has a ladder with a man of mass m on one of its ends and a counter balancing mass M on its other end. The man climbs with a velocity v_r relative to ladder. Ignoring the masses of the pulley and the rope as well as the friction on the pulley axis, the velocity of the centre of mass of this system is:

A bullet of mass m moving vertically upwards instantaneously with a velocity 'u' hits the hanging block of mass 'm' and gets embedded in it, as shown in the figure. The height through which the block rises after the collision. (assume sufficient space above block) is:

A block of mass m sliding n a smooth horizontal surface with velocity vecv meets a long horizontal spring fixed ast one end and having spring constant k as shown n figure. Find the maximum compression of the spring. Will the velocity of the block be the same as v whenit comes back to the original position shown?

Find out velocity of block B in the given figure : (all the pulleys are ideal and string are inextensible massless)

In the situation shown in figure, find the velocity of image.