The SHMs are represent by the equation `y_(1)=0.1sin(100pit+(pi)/(3))&y_(2)=0.1 cos pit`. The phase difference of the velocity of particle is

Two simple harmonic motions are represented by the equations: x_(1)=5sin(2pit+(pi)/(4)),x^(2)=5sqrt(2)(sin2pit+cos2pit) What is the ratio of their amplitudes?

Two waves are represents by the equations y_1=asin(omegat+kx+0.57)m,y_2=acos(omegat+kx)m ,where x is inmetre and t in s The phase difference between them is

A standing wave is represented by y=A sin (100t) cos (0.01x) where y and A are in millimetres. t in seconds and x in metres. The velocity of the wave is ……… .

If the displacement of a particle executing SHM, is given by y=0.30 sin (220t+0.64) in metre, then the frequency and the maximum velocity of the particle are (t is in seconds)…………….

A longitudinal wave is described by the equation y = y_(0) sin 2pi (ft - x// lambda) . The maximum particle velocity is equal to four times the wave velocity if ……….. .

The equation of a wave is y = 0.1 sin (100 pi t - kx) where x , y are in metres and t in seconds . If the velocity of the wave is 100 m/s , then the value of k is

A wave is described by equation y = (1.0 mm) sin pi ((x)/(2.0 cm) - (t)/(0.01 s)) (a) Find the time period and the wavelength. (b) Write the equation for the velocity of the particle. Find the speed of the particle at x = 1.0 cm at time t = 0.01 s . (d) What are the speeds of the particles at x = 1.0 cm at t = 0.011, 0.012 and 0.013 s ?

The number of solution of the equation 2sin^(-1)((2x)/(1+x^(2)))-pi x^(3)=0 is equal to