For a particle performing `SHM`

Ratio of kinetic energy at mean position to potential energy at A/2 of a particle performing SHM

At two particular closest instant of time t_1 and t_2 the displacements of a particle performing SHM are equal. At these instant

U.r graph of a particle performing SHM is as shown in figure. What conclusion cannot be drawn from the graph?

The figure shows a graph between velocity and displacement (from mean position) of a particle performing SHM :

Assume x= 2 cos (πt+ π/3) cm represents the position of a particle performing SHM. The initial position of particle on x-axis is

The acceleration of a particle performing SHM is 12 cm //s^(2) at a distance of 3 cm from the mean position . Calculate its time - period . Hint : a = omega^(2) x a = 12 cm//s^(2) , x=3cm Find omega T= (pi)/(omega)

The total energy of particle performing SHM depend on : -

Assertion : A particle performing SHM at certain instant is having velocity v. It again acquire a velocity v for the first time after a time interval of T second. Then the time period of oscillation is T second. Reason : A particle performing SHM can have same velocity at two instants in one cycle.

The time taken by a particle performing SHM to pass from point A and B where it is velocities are same is 2s. After another 2 s it returns to B. The time period oscillation is (in seconds)

The time taken by a particle performing SHM to pass from point A to B where its velocities are same is 2 s . After another 2 s it returns to B . The ratio of distance OB to its a amplitude (where O is the mean position) is