Following is given the equation of a travelling wave (all is SI unit)
y = (0.02) sin `2pi`(10t - 5x)
Match of following.

Following is given the eqution of a stationary wave (all in SI units) y = (0.06)sin (2pix)cos(5pit) Match of following.

The equation of a travelling wave on a string is y = (0.10 mm ) sin [31.4 m^(-1) x + (314s^(-1)) t]

The equation of a wave travelling in a string can be written as y = 3 cos pi (10t-x) . Its wavelength is

A wave is given by the equation y = 10 sin 2 pi (100 t - 0.02 x) + 10 sin 2 pi (100 t + 0.02 x) Find the loop length , frequency , velocity and maximum amplitude of the stationary wave produced.

A wave is given by the equation y = 10 sin 2 pi (100 t - 0.02 x) + 10 sin 2 pi (100 t + 0.02 x) Find the loop length , frequency , velocity and maximum amplitude of the stationary wave produced.

Two waves represented by the following equations are travelling in the same y_1 = 5 sin 2pi ( 75 t - 0.25x ) y_2 10 sin 2pi ( 150 t - 0.50x ) . The intensity ratio I_1//I_2 of the two waves is

The equation of a travelling wave is y(x, t) = 0.02 sin ((x)/(0.05) + (t)/(0.01)) m Find (a) the wave velocity and (b) the particle velocity at x = 0.2 m and t = 0.3 s .

The equation of a travelling wave is, Y = A sin 2pi (pt-x//5) Then the ratio of maximum particle velocity to wave velocity is,

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 equation of a wave travelling on a string is given by Y(mn) = 8 sin[ (5m^(-1)x-(4s^(-1)t ]. Then