the equation of a sound wave is given as `y=0.005 sin (62.4x + 316t)`. The wavelength of this wave is

The equation of a sound wave is y=0.0015sin(62.4x+316t) the wavelength of this wave is

The equuation of a wave is given by y=0.5 sin (100 t+25x) The ratio of maximum particle velolcity to wave velocity is:

The equation of a wave is represented by y=10^-4sin[100t-(x)/(10)] . The velocity of the wave will be

The equation of a progressive wave is given by y=a sin (628t-31.4x) . If the distance are expressed in cms and time seconds, then the wave in this string wll be

The equation of a sound wave at 0^(@)C is given as y=Asin(1000t-3x) the speed at some other temperature T is given 336m//s the value of T is

The equation of a travelling sound wave is y = 6.0 sin (600 t - 1.8 x) where y is measured in 10^-5m , t in second and x in metre. (a) Find the ratio of the displacement amplitude of the particles to the wavelength of the wave. (b) Find the ratio of the velocity amplitude of the particles to the wave speed.

The equation of a progressive wave is given by y=a sin (628 t-31.4 x) If the distances are expressed in cms and time in seconds, then the wave velocity will be

The equation of a simple harmonic wave is given by y = 3 sin"(pi)/(2) (50t - x) where x and y are in meters and x is in second .The ratio of maximum particle velocity to the wave velocity is

The equation of a simple harmonic wave is given by y = 3 sin"(pi)/(2) (50t - x) where x and y are in meters and x is in second .The ratio of maximum particle velocity to the wave velocity is

The equation of a wave is y=(x,t)=0.05 sin [(pi)/(2)(10x-40t)-(pi)/(4)]m find: (a) the wavelength, the frequency and the wave velocity (b) the participle velocity and acceleration at x=0.5m and t = 0.05s .