The amplitude of a wave disturbance propagating along positive X-axis is given by `=1/(1+x^(2))` at t=0 and `y=1/[1+(x-2)^(2)]` at t=4 s where x and y are in metre. The shape of wave diturbance does not change with time. The velocity of the wave is

The amplitude of wave disturbance propagating in the positive x-direction is given by y=(1)/((1+x)^(2)) at time t=0 and y=(1)/(1+(x-2)^(2)) at t=1s, where x and y are in metres. The shape of wave does not change during the propagation. The velocity of the wave will be ____m/s.

The displacement of a wave disturbance propagating in the positive x-direction is given by y =(1)/(1 + x^(2)) at t = 0 and y =(1)/(1 +(x - 1)^(2)) at t =2s where, x and y are in meter. The shape of the wave disturbance does not change during the propagation. what is the velocity of the wave?

The shape of a wave propagating in the positive x or negative x-direction is given y=1/sqrt(1+x^(2)) at t=0 and y=1/sqrt(2-2x+x^(2)) at t=1s where x and y are in meters the shape the wave disturbance does not change during propagation find the velocity of the wave

The displacement function of a wave traveling along positive x-direction is y=(1)/(2+2x^(2)) at t=0 and by y=(1)/(2+2(x-2)^(2)) at t=2s, where y and x are in metre. The velocity of the wave is:

The displacement function of a wave travelling along positive x-direction is y =(1)/(2 + 3x^(2))at t=0 and by y = (1)/(2) + 3(x - 2)^(2)) at t = 2 s , where y and x are in metre. The velocity of the wave is

The shape of a wave is represented by y=(1)/(1+x^(2)) at t=0 and y=(1)/(1+(x-1)^(2)) at t=2s . Assume that the shape of the wave remains unaltered as it advances in the medium. Find the velocity of the wave and represent the wave graphically.

A travelling wave pulse is given by y=(4)/(3x^(2)+48t^(2)+24xt+2) where x and y are in metre and t is in second. The velocity of wave is :-

A wave is represented by y=0.4cos(8t-(x)/(2)) where x and y are in metres and t in seconds. The frequency of the wave is

The equation of a progressive wave is given by y = 0.5 sin (20 x - 400 t) where xand y are in metre and tis in second. The velocity of the wave is