A simple · pendulum of length L is hanging from a rigid support on the ceiling of a stationary train. If the train moves forward with an acceleration a, then the time period of the pendulwn will be

A man measures time period of a pendulum (T) in stationary lift. If the lift moves upward with acceleration (g)/(4) , then new time period will be

The time period of a simple pendulum inside a stationary lift is T. If it starts descending with acceleration g/5. the new period of the simple pendulum will be

A simple pendulum is suspended from the roof of a train . If the train is moving with an acceleration 49 cm/s^2 . Then the angle of inclination of the string about the vertical will be

A simple pendulum of length 1 m is freely suspended from the ceiling of an elevator. The time period of small oscillations as the elevator moves up with an acceleration of 2m//s^2 is (use g=10 m//s^2 )

A thick rope of density rho and length L is hung from a rigid support. The increase in length of the rope due to its own weight is ( Y is the Young's modulus)

The length of simple pendulum executing SHM is increased by 69% The percentage increase in the time period of the pendulum is

If the length of a simple pendulum is equal to the radius of the earth, its time period will be

A particle of mass 'm' is suspended from a ceiling through a string of length'L'. If the particle moves in a horizontal circle of radius 'r', then the speed of the particle is

A simple pendulum has a time period T. If the support and the pendulum fall freely, the time period will be

A simple pendulum attached to the ceiling of a stationary lift has a time period T. The distance y covered by the lift moving upwards varies with time t as y = t^(2) where y is in metres and t in seconds. If g = 10 m//s^(2) , the time period of pendulum will be