The equation of a stationary wave is ` y = 0.8 cos ((pi x)/(20)) sin 200 pi t` where ` x` is in cm and t is in s. The separation between consecutive nodes will be

A stationary wave is given by y = 5 sin (pi x)/(3) cos 40 pi t where x and y are in cm and t is in seconds What is the distance between two successive nodes

The equation of a transverse wave is given by y=10 sin pi (0.01 x -2t ) where x and y are in cm and t is in second. Its frequency is

The equation of stationary wave along a stretched string is given by y = 5 sin(pi/3 x) cos 40pi t where x and y are in centimetre and t in second. The separation between two adjacent nodes is :

The equation of a plane progressive wave is given by y=2cos(100pit-(pix)/(20)) where x and y are in cm and t is in second. The wavelength of the wave is

The equation of a stationary a stationary wave is represented by y=4sin((pi)/(6)x)(cos20pit) when x and y are in cm and t is in second. Wavelength of the component waves is

The equation of a wave is y=4 sin[(pi)/(2)(2t+(1)/(8)x)] where y and x are in centimeres and t is in seconds.

The equation of a wave is y = 4 sin {pi/2(2t + x/8)} where y , x are in cm and time in seconds. The phase difference between two position of the same particle which are occupied at time interval of 0.4 s is x pi xx10^(-1) , what is the value of x ?

A stationary wave is given by y = 5 sin (pi x)/(3) cos 40 pi t where x and y are in cm and t is in seconds What is the velocity of a particle of the string at the position x = 1.5 cm when t = 9/8 s

The equation of a wave distrubance is a given as y= 0.02 sin ((pi)/(2)+50pi t) cos (10 pix) , where x and y are in metre and t is in second . Choose the correct statement (s).

A stationary wave is given by y = 5 sin (pi x)/( 3) cos 40 pi t where x and y are in cm and t is in second. a. What are the amplitude and velocity of the component wave whose superposition can give rise to this vibration ? b. What is the distance between the nodes ? c. What is the velocity of a particle of the string at the position x = 1.5 cm when t = 9//8 s ?