Two masses M and m are suspended together by massless spring of force constant -k. When the masses are in equilibrium, M is removed without disturbing the system. The amplitude of oscillations.

Two masses m 1 and m 2 are suspended together by a massless spring of constant K . When the masses are in equilibrium, m 1 is removed without disturbing the system. The amplitude of oscillations is

Two masses 8 kg 4 kg are suspended together by a massless spring of spring constant 1000 Nm^(-1) . When the masses are in equilibrium 8 kg is removed without disturbing the system . The amplitude of oscillation is

Two masses m_(1)and M_(2) are suspended together by a massless spring of constant k. When the masses are in equilibrium, m_(1) is removed without disturbing the system. Then the angular frequency of oscillation of m_(2) is

Two masses m_(1) and m_(2) are suspended together by a massless spring of constant k. When the masses are in equilibrium, m_(1) is removed without disturbing the system. Then the angular frequency of oscillation of m_(2) is

Two masses m_(1) and m_(2) are suspended together by a massless spring of constant K. When the masses are in equilibrium, m_(1) is removed without disturbing the system. Then the angular frequency of oscillation of m_(2) is -

Two masses m_(1) = 1kg and m_(2) = 0.5 kg are suspended together by a massless spring of spring constant 12.5 Nm^(-1) . When masses are in equilibrium m_(1) is removed without disturbing the system. New amplitude of oscillation will be

A block of mass m is suspended by different springs of force constant shown in figure.

A block of mass m hangs from a vertical spring of spring constant k. If it is displaced from its equilibrium position, find the time period of oscillations.

A mass m is suspended from a spring of force constant k and just touches another identical spring fixed to the floor as shown in the fig. The time period of small oscillations is

A block of mass m suspended from a spring of spring constant k . Find the amplitude of S.H.M.