The displacement of a particle from its mean position (in metre) is given by
`y=0.2 "sin" (10 pi t+ 1.5 pi) "cos" (10 pi t+1.5 pi)`
The motion of the particle is

The displacement of a particle from its mean position (in mean is given by y = 0.2 sin(10pi t + 1.5 pi) cos (10 pi t+ 1.5 pi) . The motion but not S.H.M.

The displacement of a particle from its mean position (in m) varies with time according to the relation y = 0.2 sin (10pit+1.5pi)cos(10pit+1.5pi) . The motion of the particle is

The displacement of a particle ( in meter ) from its mean position is given by the equation y = 0.2 ( cos^(2) "" (pi t)/( 2) - sin^(2) "" ( pi t )/( 2)) , The motion of the above particle is

The displacement of a particle is given by x = 3 sin ( 5 pi t) + 4 cos ( 5 pi t) . The amplitude of particle is

The displacement of a particle of mass 0.1 kg from . its mean position is given by, y = 0.05 sin 4pi(5t+0.4) (where all the quantities are in S.I. unit). Period of motion is 0.1 s. The total energy of the particle is

The displacement of a particle performing a S.H.M is given by x=0.25 "cos" [8 pi t+(pi)/(3)] . The frequency of S.H.M. is

The displacement of a particle performing a S.H.M. is given by x=0.5 "sin" 100 pi (t + 0.05) , where x is in metres and t is in second. Its periodic time in second is

When two sound waves travel in the same direction in a medium, the displacement of a particle located at x at time t is given by y_1=0.05 cos (0.50 pi x-10 pi t) y_2=0.05 cos (0.46 pi x-92 pi t) where y_1,y_2 and x in meters and t in seconds. The speed of sound in the medium is:

The displacement of a particle in S.H.M. is given by x=5["cos" pi t + "sin" pi t] where x is in metre. The amplitude of motion of the particle is given by