The equation `y=5sin((pix)/(25))cos(450t)` represents the stationary wave in a vibrating sonometer wire, where `x,y` are in cm and t in sec. The distances of `2nd` and `3rd` nodes from one end are (in cm).

The equation y=4cos ((2pix)/(50))sin(100pit) represents a stationary wave, where x and y are in cm, and 't' is in s. Then a node occurs at a distance of origin

The equation y=4cos ((2pix)/50) sin (200 pi t) represents a stationary wave, where x and y are in cm and t in s. Then a node occurs at a distance of origin

The equation y=4sin pi( 200t-(x/25)) represents a transverse wave that travels in a stretched wire where x, y are in cm and t in second.Its wavelength and velocity are

The equation y = 0.15 sin 5x cos 300t represents a stationary wave. The wavelength of this stationary wave will be -

The length of a sonometer wire is 90cm and the stationary wave setup in the wire is represented by an equation y=6sin((pix)/(30))cos(250t) where x , y are in cm and t is in second. The distances of successive antinodes from one end of the wire are

The equation y=0.15 sin 5 x cos 3000 t , describes a stationary wave. The wavelength of the stationary wave is

A string vibrates according to the equation y=5 sin ((2 pi x)/(3)) cos 20 pi t , where x and y are in cm and t in sec . The distance between two adjacent nodes is

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

The equation of a wave id represented as Y=2sin(Πx - 200Πf) where x and y are in cm and t is in second. The wave velocity is

A wave is represented by the equation, y = 0.1 sin (60 t + 2x) , where x and y are in metres and t is in seconds. This represents a wave