(1) A wave is traveling in the positive y direction with wavelength λ = 12 m and frequency f = 1/6 Hz. At t = 0, there is no displacement of the medium at the origin, but its amplitude is 6m.
(a) Write the equation for the displacement of this wave as a function of position and time.
(b) Draw a quantitatively accurate history graph (at y = 3m) and snapshot graph (at t = 2s).
(c) What is the speed of the wave?
(1) A wave is traveling in the positive y direction with wavelength λ = 12 m...
(1) A wave is traveling in the positive-y direction with wavelength λ “ 12 m and frequency f “ 1 6 Hz. At t “ 0, there is no displacement of the medium at the origin, but its amplitude is 6m. (a) Write the equation for the displacement of this wave as a function of position and time. (b) Draw a quantitatively accurate history graph (at y “ 3m) and snapshot graph (at t “ 2s). (c) What is the...
(1) A wave is traveling in the positive-y direction with wavelength λ f Hz. At t is 6m 12 m and frequency 0, there is no displacement of the medium at the origin, but its amplitude a) Write the equation for the displacement of this wave as a function of position and (b) Draw a quantitatively accurate history graph (at y 3m) and snapshot graph (at t 2s) (c) What is the speed of the wave?
(2) A wave passes your house (considered to be x “ 0), and you start your stopwatch as the wave passes (marking t “ 0). It is traveling at a speed of 50 m/s in the negative-x direction. The displacement of the wave as it passes your house is 4 m even though its amplitude is 6m. It has a frequency of 2 Hz. (a) Write the equation for the displacement of this wave as a function of position and...
A wave passes your house (considered to be x = 0), and you start your stopwatch as the wave passes (marking t = 0). It is traveling at a speed of 50 m/s in the negative-x direction. The displacement of the wave as it passes your house is 4 m even though its amplitude is 6m. It has a frequency of 2 Hz. (a) Write the equation for the displacement of this wave as a function of position and time....
The displacement of a wave traveling in the positive x-direction is y(x, t) = (3.5 cm)cos(2.7x - 122t), where x is in m and t is in s. (a) What is the frequency of this wave? Hz (b) What is the wavelength of this wave? m (c) What is the speed of this wave? m/s
1. The left figure is a history graph that shows the displacement D of a traveling wave at a given position as a function of time. The right figure is a snapshot graph that shows the displacement of the same wave as a function of position. D (cm) D (cm) -1 -2 2/3 4 67 8 -2 (a) Determine the period T, the frequency f, and the angular frequency o for this wave. (b) Determine the wavelength 2, wavenumber K,...
A sinusoidal wave traveling in the positive X direction has an amplitude of 0.10 m cm, a wavelength of 0.25 m, and a frequency of 50 Hz. Find the followings: For each question you Must show the symbol, formula, calculations, result, and unit Period. Angular frequency. wave number. Speed of the wave (phase velocity) Maximum speed of vibration (transverse speed) of the source of the wave Maximum acceleration of the vibration (transverse acceleration) The equation for the moving wave.
The sinusoidal wave shown in the figure below is traveling in the positive x-direction and has a frequency of 20.6 Hz. (a) Find the amplitude. cm? (b) Find the wavelength. cm? (c) Find the period. s? (d) Find the speed of the wave. m/s?
13. I The displacement of a wave traveling in the positive x-direction is D(x, t) (3.5 cm) sin(2.7x 1241), where x is in m and t is in s. What are the (a) frequency, (b) wavelength, and (c) speed of this wave? 13. I The displacement of a wave traveling in the positive x-direction is D(x, t) (3.5 cm) sin(2.7x 1241), where x is in m and t is in s. What are the (a) frequency, (b) wavelength, and (c)...
A sinusoidal wave traveling in the positive X direction has an amplitude of 10.0 cm, a wavelength of 25.0 cm, and a frequency of 5.00 Hz. c) wave function of time