The amplitude and time period in SHM are 0.8 cm and 0.2 sec respectively. If the initial phase is `pi//2` radian, then the equation representing SHM is -

The amplitude and the time period in a S.H.M. is 0.5 cm and 0.4 sec respectively. If the initial phase is pi//2 radian, then the equation of S.H.M. will be

The amplitude and the periodic time of a S.H.M. are 5 cm and 6 sec respectively. At a distance of 2.5 cm away from the mean position, the phase will be

The time period and the amplitude of a simple pendulum are 4 seconds and 0.20 meter respectively. If the displacement is 0.1 meter at time t=0, the equation on its displacement is represented by :-

Two linear SHM of equal amplitudes A and frequencies omega and 2omega are impressed on a particle along x and y - axes respectively. If the initial phase difference between them is pi//2 . Find the resultant path followed by the particle.

Three sinusodal waves having amplitudes a, a/2 and a/3 are superposed. They have the same period and thelr phase are 0, pi//2 and respectively. Find (i) The resultant amplitude and phase (ii) Draw a sketch to show the resultant wave.

A body is executing SHM with amplitude A and time period T . The ratio of kinetic and potential energy when displacement from the equilibrium position is half the amplitude

The figure shows the displacement-time graph of a particle executing SHM . If the time period of oscillation is 2s , then the equation of motion is given by

The figure shows the displacement-time graph of a particle executing SHM . If the time period of oscillation is 2s , then the equation of motion is given by

Two particles execute SHM of same amplitude and same time period, about same mean position but with a phase difference between them. At an instant they are found to cross each other at x=+(A)/(3) . The phase difference between them is

Two SHM's with same amplitude and time period, when acting together in perpendicular directions with a phase difference of (pi)/(2) give rise to