Two sinusoidal waves given below as superposed
`y_1= A sin ( kx - omega t + (pi)/(6))`

Two sinusoidal waves are superposed. Their equations are y_(1)=Asin(kx-omegat+(pi)/(6))and y_(2)=Asin(kx-omegat-(pi)/(6)) the equation of their resultant is

Two coherent waves represented by y_(1) = A sin ((2 pi)/(lambda) x_(1) - omega t + (pi)/(4)) and y_(2) = A sin (( 2pi)/(lambda) x_(2) - omega t + (pi)/(6)) are superposed. The two waves will produce

A sinusoidal wave is given by y=A sin (kx- omegat ). The ratio of its maximum particle velocity to wave velocity is

Which of the following travelling wave will produce standing wave , with nodes at x = 0 , when superimosed on y = A sin ( omega t - kx)

Which of the following travelling wave will produce standing wave , with nodes at x = 0 , when superimosed on y = A sin ( omega t - kx)

On the superposition of the two waves given as y_1=A_0 sin( omegat-kx) and y_2=A_0 cos ( omega t -kx+(pi)/6) , the resultant amplitude of oscillations will be

Two plane progressive waves are given as (y_1 = A_1 sin) (Kx -omrga t) and [y_2 = A_2 sin (Kx - omega t + phi)] are superimposed. The resultant wave will show which of the following phenomenon?

Two simple harmonic motions given by, x = a sin (omega t+delta) and y = a sin (omega t + delta + (pi)/(2)) act on a particle will be

Let the two waves y_(1) = A sin ( kx - omega t) and y_(2) = A sin ( kx + omega t) from a standing wave on a string . Now if an additional phase difference of phi is created between two waves , then

Three one-dimensional mechanical waves in an elastic medium is given as y_1 = 3A sin (omegat - kx), y_2 = A sin (omegat - kx + pi) and y_3 = 2A sin (omegat + kx) are superimposed with each other. The maximum displacement amplitude of the medium particle would be