In the figure `m_(A) = m_(B) = 1 kg`. Block A is neutral while `q_(B) = -1C`. Sizes of A and B are negligible. B is released from rest at a distance 1.8 m fromt A. Initially spring is neither compressed nor elongated.

The amplitude of oscillation of the combined mass will be

In the figure m_(A) = m_(B) = 1 kg . Block A is neutral while q_(B) = -1C . Sizes of A and B are negligible. B is released from rest at a distance 1.8 m fromt A. Initially spring is neither compressed nor elongated. Equilibrium position of the combined mass is at x = ........m.

In the figure m_(A) = m_(B) = 1 kg . Block A is neutral while q_(B) = -1C . Sizes of A and B are negligible. B is released from rest at a distance 1.8 m fromt A. Initially spring is neither compressed nor elongated. If collision between A and B is perfectly inelastic, what is velocity of combined mass just after collision ?

The block shown in figure is released from rest. Find out the speed of the block when the spring is compressed by 1 m

Two blocks of masses m_(1) and m_(2) are kept on a smooth horizontal table as shown in figure. Block of mass m_(1) (but not m_(2) is fastened to the spring. If now both the blocks are pushed to the left so that the spring is compressed a distance d. The amplitude of oscillatin of block of mass m_(1) after the system is released is

The masses in figure slide on a frictionless table. m_(1) but not m_(2) , is fastened to the spring. If now m_(1) and m_(2) are pushed to the left , so that the spring is compressed a distance d , what will be the amplitude of the oscillation of m_(1) after the spring system is released ?