If the equation of transverse wave is `y=5 sin 2 pi [(t)/(0.04)-(x)/(40)]`, where distance is in cm and time in second, then the wavelength of the wave is

S_(1) : A standing wave pattern if formed in a string. The power transfer through a point (other than node and antinode) is zero always S_(2) : if the equation of transverse wave is y= sin 2pi[t/0.04-x/40] , where distance is in cm. time in second, then the wavelength will be 40 cm. S_(3) : if the length of the vibrating string is kept constant, then frequency of the string will be directly proportional to sqrt(T)

The equation of a wave is y=5sin((t)/(0.04)-(x)/(4)) where x is in cm and t is in seccond. The velocity of the wave will be

The equation of a plane progressive wave is given by y=5cos(200t-(pi)/(150)x) where x and y in cm and t is in second. The wavelength of the wave 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 transverse wave is given by y=100 sin pi (0.04z-2t) where y and z are in cm ant t is in seconds. The frequency of the wave in Hz is

Along a stretched string equation of transverse wave is y = 3 sin [2pi ((x)/(20)-(t)/(0.01))] Where, x, y are in cm and t is in second. Calculate wave velocity.

The equation of a transverse wave is given by y = 20 sin pi (4t - 0.04x) where x and y are in m and t is in sec. The frequency of the wave is

The equation of progressive wave is y = 0.2 sin 2pi [(t)/(0.01)-(x)/(0.3)] , where x and y are in metre and t is in second. The velocity of propagation of the wave is

A wave travels in a medium according to the equation of displacement given by y(x, t)=0.03 sin pi (2 t-0.01 x) where y and x are in metres and t in seconds. The wavelength of the wave is