10) A transverse sinusoidal wave is generated at one end of a long, horizontal string by an oscillator moving up and down through a total distance of 1.00 cm. The motion is continuous at a frequency of 120 Hz. The string has a linear density of 120 g m-1 and is kept at a tension of F = 90.0 N. a. Calculate the maximum value of the transverse speed u b. Calculate the maximum value of the transverse component of tension f c. Show that the two maximum values found in (a) and (b) occur at the same phase values for the wave, and determine the transverse displacement y at this point.

10) A transverse sinusoidal wave is generated at one end of a long, horizontal string by an oscillator moving up and down through a total distance of 1.00 cm. The motion is continuous at a frequency of 120 Hz. The string has a linear density of 120 g m-1 and is kept at a tension of F = 90.0 N. a. Calculate the maximum value of the transverse speed u b. Calculate the maximum value of the transverse component of tension f c. Show that the two maximum values found in (a) and (b) occur at the same phase values for the wave, and determine the transverse displacement y at this point.

College Physics

10th Edition

ISBN:9781285737027

Author:Raymond A. Serway, Chris Vuille

Publisher:Raymond A. Serway, Chris Vuille

Chapter14: Sound

Section: Chapter Questions

Problem 47P: A steel wire with mass 25.0 g and length 1.35 m is strung on a bass so that the distance from the...

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A distance of 5.00 cm is measured between two adjacent nodes of a standing wave on a 20.0-cm-long string. (a) In which harmonic number n is the string vibrating? (b) Find the frequency of this harmonic if the string has a mass of 1.75 102 kg and a tension of 875 N.
A transverse wave on a siring is described by the wave function y=0.120sin(8x+4t) where x and y are in meters and t is in seconds. Determine (a) the transverse speed and (b) the transverse acceleration at t = 0.200 s for an element of the string located at x = 1.60 m. What are (c) the wavelength, (d) the period, and (e) the speed of propagation of this wave?
A steel wire with mass 25.0 g and length 1.35 m is strung on a bass so that the distance from the nut to the bridge is 1.10 m. (a) Compute the linear density of the string. (b) What velocity wave on the string will produce the desired fundamental frequency of the E1 string, 41.2 Hz? (c) Calculate the tension required to obtain the proper frequency. (d) Calculate the wavelength of the strings vibration. (e) What is the wave-length of the sound produced in air? (Assume the speed of sound in air is 343 m/s.)
A steel wire with mass 25.0 g and length 1.35 m is strung on a bass so that the distance from the nut to the bridge is 1.10 m. (a) Compute the linear density of the string. (b) What velocity wave on the string will produce the desired fundamental frequency of the E1 string, 41.2 Hz? (c) Calculate the tension required to obtain the proper frequency. (d) Calculate the wavelength of the strings vibration. (e) What is the wave-length of the sound produced in air? (Assume the speed of sound in air is 343 m/s.)
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