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 in series and particle is connected at the one T. Find the relation between `T, T_(1)` and `T_(2)`

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 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 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 S.H,M with a period t_(2) If the period of oscillation with two spring in .

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

The normal at t_(1) on the parabola meets again at t_(2) then find relation between t_(1) and t_(2)

The bob of simple pendulum executes SHM in water with a period T, while 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 (4000)/(3)kgm^(-3) , find the ration between T and T_(0) .

The time period of oscillations of a block attached to a spring is t_(1) . When the spring is replaced by another spring, the time period of the block is t_(2) . If both the springs are connected in series and the block is made to oscillate using the combination, then the time period of the block is

A spring of force constant K is attached with a mass executes with S.H.M has a time period T . It is cut into three equal parts The frequency of arrangement when the springs are connected in series to the parallel combination for the same load is

A simple pendulum executes S.H.M. in water with a time period T_(w) . When the bob executes S.H.M. in air, time period is T_(a) , IF the density of bob of simple pendulum is 5000/3 kg/ m^(3) and frictional force of water is neglected, then find the relation between T_(w) and T_(a) .