A 100g mass stretches a particular spring by 9.8cm, when suspended vertically from it. How large a mass must be attached to the spring if the period of vibration is to be 6.28s?

A 100 g mass stretches a particular spring by 9.8 cm, when suspended vertically from it. How large a mass must be attached to the spring if the period of vibration is to be 6.28 s?

A spring elongated by length 'L' when a mass 'M' is suspended to it. Now a tiny mass 'm' is attached and then released, its time period of oscillation is -

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 force of 6.4 N stretches a vertical spring by 0.1 m. The mass (in kg) that must be suspended from the spring so that it oscillates with a time period of (pi)/(4) second.

Two springs 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 spring are k_1 and k_2 respectively. The period of vertical oscillations of the system will be

A mass M is suspended from a light spring. An additional mass m added to it displaces the spring further by distance x then its time period is

When a mass m attached to a spring it oscillates with period 4s. When an additional mass of 2 kg is attached to a spring, time period increases by 1s. The value of m is :-

If the period of oscillation of mass M suspended from a spring is one second, then the period of 9M will be

The period of oscillation of mass M suspended from a spring of negligible mass is T. If along with it another mass M is also suspended, the period of oscillation will now be

A block with a mass of 3.00 kg is suspended from an ideal spring having negligible mass and stretches the spring by 0.2 m . (a) What is the force constant of the spring? (b) What is the period of oscillation of the block if it is pulled down and released ?