The equation of a wave travelling on a string is `y=(0.10mm)sin[3.14m^-1)x+(314s^-1)t]`. (a) In which direction does the wave travel ? (b) Find the wave speed, the wavelength and the frequency of the wave. (c) What is the maximum displacement and the maximum speed of a portion of the string ?

The equation of a wave travelling on a string is y = (0.10 mm) sin [(31.4 m^(-1)) x + (314 s^(-1))t] (a) In which direction does the travel? (b) Find the wave speed, the wavelength and the frequency of the wave. ( c ) What is the maximum displacement and the maximum speed of a portion of the string?

The equation of a wave travelling on a string is y = (0.10 mm) sin [(31.4 m^(-1)) x + (314 s^(-1))t] (a) In which direction does the travel? (b) Find the wave speed, the wavelength and the frequency of the wave. ( c ) What is the maximum displacement and the maximum speed of a portion of the string?

The equation of a travelling wave on a string is y = (0.10 mm ) sin [31.4 m^(-1) x + (314s^(-1)) t]

The equational of a stationary wave in a string is y=(4mm) sin [(314m^(-1)x] cos omegat . Select the correct alternative (s).

The equational of a stationary wave in a string is y=(4mm) sin [(314m^(-1)x] cos omegat . Select the correct alternative (s).

A sound wave travels at a speed of 339 m//s . If its wavelength is 1.5 cm , what is the frequency of the wave ? Will it be audible ?

A sound wave travels at a speed of 339 m//s . If its wavelength is 1.5 cm , what is the frequency of the wave ? Will it be audible ?

The equation for a wave travelling in x-direction on a string is y = (3.0cm)sin[(3.14 cm^(-1) x - (314s^(-1))t] (a) Find the maximum velocity of a particle of the string. (b) Find the acceleration of a particle at x =6.0 cm at time t = 0.11 s.