The vertical extension in a light spring by a weight of 1 kg suspended from the wire is 9.8 cm . The period of oscillation

When a mass M is suspended from a spring, its period of oscillation is 2 second. If a mass 4 M is suspended from the same spring, then its period of oscillation will be

1 kg weight is suspended to a weightless spring and it has time period T. If now 4 kg weight is suspended from the same spring the time period will be

The period of oscillation of a mass M suspended from a spring of spring constant K is T. the time period of oscillation of combined blocks is

A spring has a certain mass suspended from it and its period for vertical oscillation is T. The spring is now cut into two equal halves and the same mass is suspended from one of the halves. The period of vertical oscillation is now

When a mass of 1 kg is suspended from a spring, it is stretched by 0.4m. A mass of 0.25 kg is suspended from the spring and the spring is allowed to oscillate. If g=10 m//s^(2) , then its period of oscillation will be

The length of a weigtless spring increaes by 2cm when a weight of 1.0kg in the period of oscillation of the spring and its kinetic energy of oscillation. Take g=10ms^(-2) .

If the period of oscillation of mass M suspended from a spring is one second, then the period of 4M will be

A pan with a set of weights is attached to a light spring. The period of vertical oscillations is 0.5s . When some additional weights are put in pan, the period of oscillations increases by 0.1s . The extension caused by the additional weights is

A spring has a certain mass suspended from it and its period for vertical oscillations is T_(1) . The spring is now cut into two equal halves and the same mass is suspended from one of the half. The period of vertical oscillation is now T_(2) . The ratio of T_(2)//T_(1) is