A ball of mass 5 kg hanging from a spring oscillates with a time period of `2 pi s`. At any instant the ball is at equilibrium position, now the ball is removed, then spring shortens by

A ball of mass 2kg hanging from a spring oscillates with a time period 2pi seconds. Ball is removed when it is in equilibrium position, then spring shortens by

A ball of mass m kg hangs from a spring of spring constant k . The ball oscillates with a period of T seconds if the ball is removed, the spring is shortened( w.r.t. length in mean position) by

A block of mass M suspended from a spring oscillates with time period T . If spring is cut in to two equal parts and same mass M is suspended from one part, new period os oscillation is

A body of mass 4.9 kg hangs from a spring and oscillates with a period 0.5 s. On the removal of the body, the spring is shortened by (Take g=10m s^(-2), pi^(2)=10 )

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.

In the given figure, a mass M is attached to a horizontal spring which is fixed on one side to a rigid support. The spring constant of the spring is k. The mass oscillates on a frictionless surface with time period T and amplitude A. When the mass is in equilibrium position, as shown in the figure, another mass m is gently fixed upon it. The new amplitude of oscillation will be :

A mass suspended on a vertical spring oscillates with a period of 0.5s . When the mass is allowed to hang at rest, the spring is stretched by

A block of mass 0.5 kg hanging from a vertical spring executes simple harmonic motion of amplitude 0.1 m and time period 0.314s. Find the maximum fore exerted by the spring on the blockl.

A mass m attached to a light spring oscillates with a period of 2 s. If the mass is increased by 2 kg, the period increases by 1 s. Then the value of m is