A small mass executes linear `S.H.M.` executes linear `S.H.M.` about `O` with amplitude `'a'` and period `'T'`. Its displacement from `O` at time `T//8` after passing through `O` is

A small mass executes linear SHM about O with amplitude a and period T . Its displacement from O at time T//8 after passing through O is:

The amplitude of a particle executing SHM about O is 10 cm . Then

A body of mass m is executing SHM with amplitude a. When its displacement x=1 unit, the force is b then what will be its maximum kinetic energy?

A particle executes SHM on a straight line path. The amplitude of oscillation is 2 cm. When the displacement of the particle from the mean position is 1 cm, the magnitude of its acceleration is equal to that of its velocity. Find the time period, maximum velocity and maximum acceleration of SHM.

A particle of mass m executes simple harmonic motion with amplitude a and frequency v. The average kinetic energy during its motion from the position of equilinrium to the end is.

The time period of a particle executing SHM is T . After a time T//6 after it passes its mean position, then at t = 0 its :

A particle executes SHM with time period T and amplitude A . The maximum possible average velocity in time T//4 is-

A particle executes linear simple harmonic motion with an amplitude of 3 cm. When the particle is at 2 cm from the mean position, the magnitude of its velocity is equal to that of its acceleration. Then its time period in second is…….

A particle executes two types of SHM. x_(1) = A_(1) sin omega t " and "x_(2) = A_(2) sin [omega t+(pi)/(3)] , then find the displacement at time t=0.

Two particles are in SHM in a straight line about same equilibrium position. Amplitude A and time period T of both the particles are equal. At time t=0 , one particle is at displacement y_(1)=+A and the other at y_(2)=-A//2 , and they are approaching towards each other. after what time they cross each other?