The displacement equation of a travelling wave puise is given as `[y= 10/ (X^2 + 12xt + 36t^2 + 25) (where x and y are in meter). The speed and direction of propagation of the wave pulse is

The equation of a moving progressive wave is given by y= 1/(x^2-4xt+4t^2+8) , where x and y are in metre and t is in second . Hence speed and direction of propagation of pulse is

The displacement equation of a traveling wave pulse, moving along X axis is given by y=(8)/(4+x^(2)) at t=0 and at t=1 y=(8)/((x^(2)-10x+29)) What is the speed and direction of the pulse?

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 :-

The equation of a progressive wave is y=0.02sin2pi[(t)/(0.01)-(x)/(0.30)] here x and y are in metres and t is in seconds. The velocity of propagation of the wave is

The wave function of a pulse is given by y= (3)/((2x+3t)^(2)) where x and y are in metre and t is in second (i) Identify the direction of propagation. (ii) Determine the wave velocity of the pulse.

A travelling wave is given by y=(0.8)/((3x^(2)+24xt+48t^(2)+4)) where x and y are in metres and t is in seconds. Find the velocity in m//s .

The wave funcation for a travelling wave on a string in given as y (x, t) = (0.350 m) sin (10 pi t - 3pix + (pi)/(4)) (a) What are the speed and direction of travel of the wave ? (b) What is the vertical displacement of the string at t = 0, x = 0.1 m ?

The wave function of a pulse is given by y=(5)/((4x+6t)^(2)) where x and y are in metre and t is in second :- (i) Identify the direction of propagation (ii) Determine the wave velocity of the pulse

If the equation of a travelling wave is given as y = 40 cos (1600t + 6x), (where y is in millimeter, t is in second and x is in meter), then ratio of the wave speed to the maximum particle speed will be

A travelling wave pulse is given by y = (10)/(5 + (x + 2t)^(2)) Here, x and y are in meter and t in second. In which direction and with what velocity is the pulse propagation. What is the ampitude of pulse?