In a wave motion `y = asin (kx - omega t),y` can represent :-

In a wave motion y = a sin (kx - omegat) , y can represent

y(xt)=asin(kx-omegat+phi) represents a

A wave is represented by the equation y = a sin(kx - omega t) is superimposed with another wave to form a stationary wave such that the point x = 0 is a node. Then the equation of other wave is :-

The equation of a light wave is written as y=Asin(kx-omegat) . Here y represents

A transverse wave travelling along the positive x-axis, given by y=A sin (kx - omega t) is superposed with another wave travelling along the negative x-axis given by y=A sin (kx + omega t) . The point x=0 is

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

Statement-1 : The superposition of the waves y_(1) = A sin(kx - omega t) and y_(2) = 3A sin (kx + omega t) is a pure standing wave plus a travelling wave moving in the negative direction along X-axis Statement-2 : The resultant of y_(1) & y_(2) is y=y_(1) + y_(2) = 2A sin kx cos omega t + 2A sin (kx + omega t) .

The stationary wave y = 2a sinkx cos omega t in a stretched string is the result of superposition of y_(1)=a sin(kx-omegat) and

In the wave equation, y = Asin(2pi)/(a)(x-bt)

The stationary wave y = 2a sin kx cos omega t in a closed organ pipe is the result of the superposition of y = a sin( omega t — kx) and