Two spring are joined and attached to a mass of 16 kg. the system is then suspended vertically from a rigid support. The spring constant of the two springs are `k_1 and k_2` respectively. The period of vertical oscillations of the system will be

Spring mass system is shown in figure. find the time period of vertical oscillations. The system is in vertical plane.

Two identical massless springs A and B consist spring constant k_(A) and k_(B) respectively. Then :

Find the period of a vertical spring - block system by both methods.

The effective spring constant of two spring system as shown in figure will be

A mass m is suspended from the two coupled springs connected in series. The force constant for springs are k_(1) and k_(2). The time period of the suspended mass will be

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

Two particles (A) and (B) of equal masses are suspended from two massless spring of spring of spring constant k_(1) and k_(2) , respectively, the ratio of amplitude of (A) and (B) is.

A light pulley is suspended at the lower end of a spring of constant k_(1) , as shown in figure. An inextensible string passes over the pulley. At one end of string a mass m is suspended, the other end of the string is attached to another spring of constant k_(2) . The other ends of both the springs are attached to rigid supports, as shown. Neglecting masses of springs and any friction, find the time period of small oscillations of mass m about equilibrium position.

The two masses m_(1) and m_(2) are joined by a spring as shown. The system is dropped to the ground from a height. The spring will be

A block of known mass is suspended from a fixed support through a ligh spring. Can you find the time period of vertical oscillation only by measuring the extension of the spring when the block is in equilibrium?