A seconds pendulum is mounted in a rocket. Its period of oscillation decreases when the rocket

A pendulum is suspended in a lit and its period of oscillation is T_(0) when the lift is stationary. (i) What will be the period T of oscillation of pendulum, if the lift begins to accelerates downwards with an acceleration equal to (3g)/(4) ?

A pendulum is suspended in a ligt and its period of oscillation when the lift is stationary is T_(a) . What must be the accleraion of the lift for the period of oscillation of the pendulum to be T_(0)//2 ?

When the point of suspendion of pendulum is moved, its period of oscillation

A simple pendulum is suspended from the ceiling of a car and its period of oscillation is T when the car is at rest. The car starts moving on a horizontal road with a constant acceleration g (equal to the acceleration due to gravity, in magnitude) in the forward direction. To keep the time period same, the length of th pendulum

The mass and the diameter of a planet are three times the repective value for the Earth. The period of oscillation of a simple pendulum on the Earth is 2 s. The period of oscillation of the same pendulum on the planet would be:

Assertion: If bob of a simple pendulum is kept in a horizontal electric field, its period of oscillation will remain same. Reason: If bob is charged and kept in horizontal electric field, then the time period will be decreased.

What is a torsional pendulum ? Name the factors on which its period of oscillation depends ?

The period of oscillation of a suspended thin cylindrical magnet is 4 seconds. It is broken into exactly two halves. Find the period of oscillation of each half when freely suspended.

The second's pendulum is taken from earth to moon, to keep time period constant (a) the length of the second's pendulum should be decreased (b) the length of the second's pendulum should be increased ( c) the amplitude should increase (d) the amplitude should decrease.

A pendulum suspended from the ceiling of the train has a time period of two seconds when the train is at rest, then the time period of the pendulum, if the train accelerates 10 m//s^(2) will be (g=10m//s^(2))