A body of mass `m` is suspended from three springs as shown in figure. If mass `m` is displaced slightly then time period of oscillation is

A block of mass m hangs from three springs having same spring constant k. If the mass is slightly displaced downwards, the time period of oscillation will be

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

The time period of small oscillations of mass m :-

A mass is suspended separately by two springs of spring constants k_(1) and k_(2) in successive order. The time periods of oscillations in the two cases are T_(1) and T_(2) respectively. If the same mass be suspended by connecting the two springs in parallel, (as shown in figure) then the time period of oscillations is T. The correct relations is

A spring of stiffness constant k and natural length l is cut into two parts of length 3l//4 and l//4 , respectively, and an arrangement is made as shown in figure . If the mass is slightly displaced , find the time period of oscillation.

figure (a) and (b) represent spring- block system. If m is displacement slightly , find the time period of ascillation of the system.

A body of mass 'm' hangs from three springs, each of spring constant 'k' as shown in the figure. If the mass is slightly displaced and let go, the system will oscillate with time period–

A body of mass m is suspended from vertical spring and is set into simple harmonic oscillations of time period T. Next the spring is fixed at one end on a smooth horizontal table and same body is attached at the other end. The body is pulled slightly and then released to produce horizontal oscillations of the spring. The time period of horizontal oscillations is

A block of mass m is attached to a cart of mass 4m through spring of spring constant k as shown in the figure. Friction is absent everywhere. The time period of oscillations of the system, when spring is compressed and then released, is

Block of mass m_(2) is in equilibrium as shown in figure. Anotherblock of mass m_(1) is kept gently on m_(2) . Find the time period of oscillation and amplitude.