Equations of a stationery and a travelling waves are `y_(1)=a sin kx cos omegat and y_(2)=a sin (omegat-kx)` The phase differences between two between `x_(1)=(pi)/(3k)` and `x_(2)=(3pi)/(2k) are phi_(1) and phi_(2)` respectvely for the two waves. The ratio `(phi_(1))/(phi_(2))`is

Two waves are given by y_(1)=asin(omegat-kx) and y_(2)=a cos(omegat-kx) . The phase difference between the two waves is -

Equations of a stationary and a travelling waves are as follows y_(1) = sin kx cos omega t and y_(2) = a sin ( omega t - kx) . The phase difference between two points x_(1) = pi//3k and x_(2) = 3 pi// 2k is phi_(1) in the standing wave (y_(1)) and is phi_(2) in the travelling wave (y_(2)) then ratio phi_(1)//phi_(2) is

Two SHM's are represented by y = a sin (omegat - kx) and y = b cos (omegat - kx) . The phase difference between the two is :

The phase difference between the waves y=acos(omegat+kx) and y=asin(omegat+kx+(pi)/(2)) is

if x = a sin (omegat + pi//6) and x' = a cos omega , t, then what is the phase difference between the two waves

Two waves are given as y_1=3A cos (omegat-kx) and y_2=A cos (3omegat-3kx) . Amplitude of resultant wave will be ____

Two particle are executing simple harmonic motion. At an instant of time t their displacement are y_(1)=a "cos"(omegat) and y_(2)=a "sin" (omegat) Then the phase difference between y_(1) and y_(2) is

Two waves y_1 = A sin (omegat - kx) and y_2 = A sin (omegat + kx) superimpose to produce a stationary wave, then

Two waves of equation y_(1)=acos(omegat+kx) and y_(2)=acos(omegat-kx) are superimposed upon each other. They will produce

Two simple harmonic motions are given by y_(1) = a sin [((pi)/(2))t + phi] and y_(2) = b sin [((2pi)/( 3))t + phi] . The phase difference between these after 1 s is