A particle at the end of a spring executes simple harmonic motion with a period `t_(1)` while the corresponding period for another spring is `t_(2)` if the oscillation with the two springs in series is T then

A particle at the end of a spring executes simple harmonic motion with a period t_1 , while the corresponding period of another spring is t_2 . If the period of oscillation with the two springs in series is T. Then

A body at the end of a spring executes SHM with a period t_(1), while the corresponding period for another spring is t_(2), If the period of oscillation with the two spring in series is T, then

A particle connected at the end of a spring executes SHM with a period T_(1) . While the corresponding period for another spring is T_(2) . When the two springs are connected inseries and particle is ocnnected at the one T. Find the relation between T, T_(1) and T_(2)

A particle at the end of a spring executes S.H,M with a period t_(2) If the period of oscillation with two spring in .

If particle is excuting simple harmonic motion with time period T, then the time period of its total mechanical energy is :-

A particle executing simple harmonic motion with time period T. the time period with which its kinetic energy oscilltes is

A particle undergoes simple harmonic motion having time period T. The time taken in 3/8th oscillation is

The bob of a simple pendulum executes simple harmonic motion in water with a period t , white the period of oscillation of the bob is t_(0) in air. Neglecting frictional force of water and given that the density of the bob is (4//3) xx 1000 kg//m^(3) , "Find" (1)/(t_(0)) .

A loaded vertical spring executes simple harmonic oscillations with period of 4 s. The difference between the kinetic energy and potential energy of this system oscillates with a period of