The equation of a wave travelling in a string can be written as ` y=3cos pi ( 100 t- x) .` Its wavelength is

The equation of a progressive wave traveling on a stretched string is y = 10sin 2pi ((t/0.02)-(x/100)) where x and y arein cm and t is in sec. What is the speed of the waves?

The equetion of a wave travelling on a string is y = 4 sin(pi)/(2)(8t-(x)/(8)) if x and y are in centimetres, then velocity of waves is

The equation of a transverse wave on a stretched string is , y = 2 sin 2 (pi) [ t / 0.04 - x / 40 ] where distances are in meter and time in second .Find the velocity of the wave.

The equation of a transverse wave on a stretched string is , y = 2 sin 2 (pi) [ t / 0.04 - x / 40 ] where distances are in meter and time in second .Find the frequency

The equation of a transverse wave on a stretched string is , y = 2 sin 2 (pi) [ t / 0.04 - x / 40 ] where distances are in meter and time in second .Find the amplitude

The equation of sound wave travelling along negative X-direction is given by, y= 0.04 sin pi (500t +1.5x)m. The shortest distance between two particles having phase difference of pi at the same instant is

The equation of a transverse wave along a stretched string is given by y = 5 sin 2 (pi) [ t / 0.04 - x /40] where the length is expressed in cm and time in second . Calculate the wavelength , frequency and velocity of the wave.

The equation of a standing wave is given by y = 0.02 cos (pi)(x) sin (100 (pi) t )m . Find the amplitude of either wave interfering , wavelength , time period, frequency and wave velocity of interfering waves.

The equation of a travelling wave is y=60 cos(1800t-6x) where y is in microns, t in seconds and x in metres. The ratio of maximum particle velocity to velocity of wave propagation is

The equations of two sound waves are given by, y_1 = 3sin ( 100 pi t ) and y_2 =4sin ( 150 pi t ) , The ratio of intensites of sound produced in the medium is