If at `t = 0`, a travelling wave pulse on a string is described by the function.
`y = (6)/(x^(2) + 3)`
What will be the waves function representing the pulse at time `t`, if the pulse is propagating along positive x-axis with speed `4m//s`?

If at t = 0 , a travelling wave pulse in a string is described by the function, y = (10)/((x^(2) + 2 )) Hence, x and y are in meter and t in second. What will be the wave function representing the pulse at time t , if the pulse is propagating along positive x-axix with speed 2 m//s ?

At t = 0 , a transverse wave pluse in a wire is described by the funcation y = (6)/(x^(3) + 3) where x and y are in meters write the funcation y(x, t) that describes this wave if it is travelling in the positive x direction with a speed of 4.5 m//s .

A pulse travelling at a speed of 2m/s along the positive Z-axis is given by y = (3)/( z^(2)+1) at t= 0 .The wave function representing the pulse at any times is given by

At t=0, a transverse wave pulse in a wire is described by the function y=6//(x^(2)-3) where x and y are in metres. The function y(x,t) that describes this wave equation if it is travelling in the positive x direction with a speed of 4.5 m//s is

At t=0, transverse pulse in a wire is described by the function y=(6)/(x^(2)+3) where x and y are in metres. Write the function y(x,t) that describe this plus if it is travelling in the positive x-direction with a speed of 4.50 m//s .

A wave pulse on a horizontal string is represented by the function y(x, t) = (5.0)/(1.0 + (x - 2t)^(2)) (CGS units) plot this function at t = 0 , 2.5 and 5.0 s .

At t=0, the shape of a travelling pulse is given by y(x,0)=(4xx10^(-3))/(8-(x)^(-2) where x and y are in metres. The wave function for the travelling pulse if the velocity of propagation is 5 m//s in the x direction is given by

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?

A travelling wave is found to have the displacement by y= (1)/(1+x^2) at t = 0, after 3 sec the wave pulse is represented by equation y=(1)/(1+(1+x)^2) .The velocity of wave is: