If block A is moving horizontally with velocity `v_(A)`, then find the velocity of block B at the instant as shown in fig.

The velocity of the block B is:

The block A is moving downward with constant velocity v_(0.) Find the velocity of the block B. When the string makes an angle theta with the horizontal

A rod AB is shown in figure. End A of the rod is fixed on the ground. Block is moving with velocity 2 ms^-1 towards right. The velocity of end B of rod at the instant shown in figure is

An inextensible string AB is tied to a block B of negligible dimensions and passes over a small pulley C so that free end A hangs h unit above the ground on which the block B rests. In this initial position shown in fig. The free end A is h unit below C. if now end A moves horizontally with a velocity v_(0) , obtain an expression for the velocity of the block at any time t.

A disc of radius R is moving on a rough horizontal surface with velocity v and angular speed omega at an instant as shown in figure. Choose the correct statement.

Block B moves to the right with a constant velocity v_(0) . The velocity of body a relative to b is

Find the angular velocity of A with respect to O at the instant shown in (Fig. 5.165). .

The block shown is moving with constant velocity. Find mu_(k) between the block and the surface.

A block of mass m moving with velocity v_(0) on a smooth horizontal surface hits the spring of constant k as shown. The maximum compression in spring is

In the system shown, the block A is moving down eith velocity v_(1) and C is moving up with velocity v_(3) . Express velocity of the block B in terms of velocities of the blocks a and C.