You listen to music in a noisy environment (loud rumbling of an aircraft), resulting in the signal f(t)in figure 1. To hear the music better, you turn on the canceling noise option of your fancyheadphones. The headphone performs the Fourier transform shown in figure 2, filters out the smallamplitude components, and sends the filtered sound of figure 3 to your ear.(a) What are the principal frequencies of the unfiltered signal?(b) Write a function f(t) that represents the filtered sound.(c) The human ear associates the pitch of a note to the lowest frequency of a periodic signal.What is that frequency:According to the Fourier transform in figure 2.According to the filtered signal shown in figure 3.Use this information to explain how to produce a low pitch sound when your speakers can generateonly frequencies higher than 100Hz.Sound = music + random noiseFourier transform of sound = music + noiseFiltered Sound = music(1)44201020 30 40 50 60t(milliseconds)70Figure 10.80.6-0.4-0.2f(t)350100 15020025030001020f(Hz)Figure 2им30 40t (milliseconds)Figure 3506070

a. We must examine the Fourier transform depicted in Figure 2 in order to ascertain the major…

Answered: You listen to music in a noisy…

University Physics Volume 1

18th Edition

ISBN:9781938168277

Author:William Moebs, Samuel J. Ling, Jeff Sanny

Publisher:William Moebs, Samuel J. Ling, Jeff Sanny

Chapter17: Sound

Section: Chapter Questions

Problem 30P: Consider a sound wave moving through the air modeled with the equation...

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Consider a sound wave moving through the air modeled with the equation s(x,t)=6.00nmcos(54.93m1x18.84103s1t) . What is the shortest time required for an air molecule to move between 3.00 nm and -3.00 nm?
a) Assume the speed of sound is 343 m/s in a room. What is the wavelength produced by a tuning fork at 262 Hz? (this is approximately the frequency of middle C on a piano) b) Let there be two speakers, A and B, emitting sound with matched phase. If a microphone is originally exactly between A and B (so that the distance to each is L), how far to the left do we need to move it so that the microphone detects destructive interference? c) Would a person at the position in (b) hear anything? Why? d) If the microphone moves vertically on the page (let this be the y-axis) how does the total intensity vary with vertical distance? Let each speaker emit intensity lo a distance 1 meter from the source. e) How long would it take for a sound pulse to travel from A to B if L = 100 meters? %3|
As a target is changing the angle from the view of a radar its velocity is observed as decreasing but its range is increasing and it follows sinusoidal(1+sinθ). Calculate the doppler phase shift of a varying range of a target that increase by a change in angle from 00 upto 900, for every 150 . If the initial range from the target is 100mt, and the frequency is 2GHz.Prepare a table of range and phase values for all of them in an order from 00 upto 900, with a change of 150. Then plot the graph between angle, Change in range and phase shift.
Suppose a flutist plays a 523-Hz C note with first harmonic displacement amplitude A1 = 100 nm. From as shown read, by proportion, the displacement amplitudes of harmonics 2 through 7. Take these as the values A2 through A7 in the Fourier analysis of the sound and assume B1 = B2 = ... = B7 = 0. Construct a graph of the waveform of the sound. Your waveform will not look exactly like the flute waveform as shown because you simplify by ignoring cosine terms; nevertheless, it produces the same sensation to human hearing.
A violinist on stage plays a middle C note of 262HZ on a day when the speed of sounds is 343m/s. The sounds is emitted in unison from two speakers in the picture. Two people stand at the point A&B in the picture, distances shown below. Which of the two people will hear completely destructive interference if any? Justify your answer.
A music song recorded in a studio is stored as a digital sequence on a CD. The analog signal representing the music is 2 minutes long and is sampled at a frequency fs=44100s-1 . How many samples should be stored on the CD? Write the number of samples without commas or dots. Assume that the audio file is mono, or in other words, single channel.
Two sound waves, which are initially in phase, travel two different distances, x1and x2toan observer/listener. Write a sentence or two about how the difference in distance, Δx,relates to the wavelength of the sound if the listenerhears maximum constructiveinterference at this location.
If a plane wave is reflected from the ocean floor with a 15 dB reduction in amplitude at an angle of incidence of 30º, what are the possible values of the specific acoustic impedance of the fluid bottom material if it has a speed of sound of 1666m/s? Answers 1.011x^6 and 2.07x10^6 please if you don't get those answers you're doing it wrong, don't upload the wrong answer I would appreciate it.
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There are two loudspeakers 3.0 m apart and both are playing a 686 Hz tone in phase.The speed of sound is 343 m/s. A person is standing directly in front of one of thetwo loudspeakers as shown in the figure and can only move along a line AB.a) Write the inherent phase difference.b) Write the pathlength difference in terms of x, which is a distance from thespeaker 1 to the person.c) At what distances x (calculate three values corresponding to integersm=0,1,2) from the speaker 1 do you hear a minimum sound intensity?
Question 4 (a) Write your understanding about coherent waves. (b) A loudspeaker hanging on a long rod radiates sound waves uniformly in all directions. At a distance of 15.0 m from the speaker, the sound intensity is 0.25 W/m². At what distance is the intensity 0.1 W/m²? Question 5 (a) A 1.4-kg 15-cm-diameter solid sphere is rotating about its diameter at 70 rev/min. What is its kinetic energy? (b) Explain why you expect an object made of a stiff material to vibrate at a higher frequency than a similar object made of a more flexible material.

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