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Chapter 36: Problem 54

A loudspeaker having a diaphragm that vibrates at 1250 \(\mathrm{Hz}\) is traveling at 80.0 \(\mathrm{m} / \mathrm{s}\) directly toward a pair of holes in a very large wall in a region for which the speed of sound is 344 \(\mathrm{m} / \mathrm{s}\) . You observe that the sound coming through the openings first cancels at \(\pm 127^{\circ}\) with respect to the original direction of the speaker when observed far from the wall. (a) How far apart are the two openings? (b) At what angles would the sound first cancel if the source stopped moving?

Short Answer

Expert verified
(a) The openings are 0.194 m apart. (b) The angles are ±45° if the source stops moving.

Step by step solution

01

Calculate the wavelength using the speed of sound

To find the wavelength, we need to use the formula \(\lambda = \frac{v}{f}\), where \(v\) is the speed of sound and \(f\) is the frequency of the sound emitted by the loudspeaker. Here, \(v = 344 \, \text{m/s}\) and \(f = 1250 \, \text{Hz}\). Calculating gives: \[ \lambda = \frac{344}{1250} = 0.2752 \, \text{m} \]
02

Adjust frequency for Doppler effect (Source moving)

The frequency observed when the sound source is moving towards the observer is given by \( f' = f \times \frac{v + v_0}{v}\), where \(v_0\) is the speed of the source and \(v\) is the speed of sound. Here, \(v_0 = 80.0 \, \text{m/s}\). Thus, \[ f' = 1250 \times \frac{344 + 80}{344} \approx 1541 \, \text{Hz} \]
03

Calculate new wavelength with adjusted frequency

Using the adjusted frequency \(f'\), calculate the new wavelength \(\lambda' = \frac{v}{f'}\): \[ \lambda' = \frac{344}{1541} \approx 0.223 \text{ m} \]
04

Use double slit interference to find separation (Source moving)

Sound cancels when the path difference \(d \sin \theta = \left(n + \frac{1}{2}\right)\lambda'\) where \(n\) is an integer. For the first cancellation, \(n = 0\). Given \(\theta = 127^{\circ}\), use \(\lambda'\): \[ d = \frac{0.5 \times 0.223}{\sin(127^{\circ})} \approx 0.194 \text{ m} \]
05

Determine angles for sound cancellation (Source stationary)

When the source is stationary, use the original frequency \(f\) and wavelength \(\lambda\). Using \( d \sin \theta = \left(n + \frac{1}{2}\right)\lambda \) with \(d = 0.194\) m and \(n=0\), solve: \[ \sin \theta = \frac{0.5 \times 0.2752}{0.194} \approx 0.709 \] So, \(\theta \approx 45^{\circ}\) or \(-45^{\circ}\).

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Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Wave Interference
Wave interference occurs when two sound waves meet and affect one another. This can be constructive, where the waves add together to make a louder sound, or destructive, where the waves cancel each other out, resulting in silence or a softer sound. In the case of the exercise, we focus on destructive interference. This happens when the waves are out of phase by 180 degrees or half a wavelength.

To visualize, imagine ripples in a pond. When two sets of ripples intersect, they can form larger waves or flatter areas depending on how the peaks and troughs align. For sound waves, this phenomenon is critical in devices like noise-canceling headphones, which use destructive interference to reduce unwanted noise.

The exercise details sound canceling at specific angles. This is due to the sound waves from the two openings meeting such that their crests and troughs perfectly align to cancel out.
Sound Waves
Sound waves are longitudinal waves that travel through a medium, like air or water. They consist of compressions and rarefactions, which are areas where air molecules are bunched together or spread apart.

The loudspeaker in the exercise creates sound waves by vibrating at a set frequency of 1250 Hz. This means the diaphragm moves back and forth 1250 times each second, pushing air particles with each movement.

We measure the speed of sound at 344 m/s in the given exercise conditions. This speed can vary based on factors like temperature, humidity, and air pressure. In the exercise, the speed and frequency are used to calculate the wavelength of sound, which helps in understanding interference patterns.
Frequency Calculation
Frequency calculation is essential in understanding how sound changes when the source or observer is in motion, known as the Doppler Effect.

In our exercise, the loudspeaker moves toward the observer, and the frequency seems higher than when it's stationary. This shift occurs because each sound wave is emitted from a slightly closer position, compressing the waves. The formula used is \[ f' = f \times \frac{v + v_0}{v} \] where \( f \) is the original frequency, \( v \) is the speed of sound, and \( v_0 \) is the speed of the source.

For the moving loudspeaker, the frequency adjusts to approximately 1541 Hz from the original 1250 Hz. This altered frequency has a shorter wavelength, affecting where and how interference occurs. Understanding these calculations can explain experiences like the change in pitch of a passing siren.

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Most popular questions from this chapter

A slit 0.360 \(\mathrm{mm}\) wide is illuminated by parallel rays of light that have a wavelength of 540 \(\mathrm{nm}\) . The diffraction pattern is observed on a screen that is 1.20 \(\mathrm{m}\) from the slit. The intensity at the center of the central maximum \(\left(\theta=0^{\circ}\right)\) is \(I_{0}\) . (a) What is the distance on the screen from the center of the central maximum to the first minimum? (b) What is the distance on the screen from the center of the central maximum to the point where the intensity has fallen to \(I_{0} / 2 ?(\text { See Problem } 36.53 \text { , part (a), for a hint about how to }\) solve for the phase angle \(\beta . )\)

Monochromatic light of wavelength \(\lambda=620 \mathrm{nm}\) from a distant source passes through a slit 0.450 \(\mathrm{mm}\) wide. The diffraction pattern is observed on a screen 3.00 \(\mathrm{m}\) from the slit. In terms of the intensity \(I_{0}\) at the peak of the central maximum, what is the intensity of the light at the screen the following distances from the center of the central maximum: (a) \(1.00 \mathrm{mm} ;\) (b) 3.00 \(\mathrm{mm}\) ; (c) 5.00 \(\mathrm{mm}\) ?

A diffraction grating has 650 slits \(/ \mathrm{mm}\) . What is the highest order that contains the entire visible spectrum? (The wavelength range of the visible spectrum is approximately \(400-700 \mathrm{nm} . )\)

A series of parallel linear water wave fronts are traveling directly toward the shore at 15.0 \(\mathrm{cm} / \mathrm{s}\) on an otherwise placid lake. A long concrete barrier that runs parallel to the shore at a distance of 3.20 \(\mathrm{m}\) away has a hole in it. You count the wave crests and observe that 75.0 of them pass by each minute, and you also observe that no waves reach the shore at \(\pm 61.3 \mathrm{cm}\) from the point directly opposite the hole, but waves do reach the shore everywhere within this distance. (a) How wide is the hole in the barrier? (b) At what other angles do you find no waves hitting the shore?

Intensity Pattern of \(N\) Slits. (a) Consider an arrangement of \(N\) slits with a distance \(d\) between adjacent slits. The slits emit coherently and in phase at wavelength \(\lambda\) . Show that at a time \(t,\) the electric field at a distant point \(P\) is $$ \begin{aligned} E_{P}(t)=& E_{0} \cos (k R-\omega t)+E_{0} \cos (k R-\omega t+\phi) \\ &+E_{0} \cos (k R-\omega t+2 \phi)+\cdots \\ &+E_{0} \cos (k R-\omega t+(N-1) \phi) \end{aligned} $$ where \(E_{0}\) is the amplitude at \(P\) of the electric field due to an individual slit, \(\phi=(2 \pi d \sin \theta) / \lambda, \theta\) is the angle of the rays reaching \(P(\text { as measured from the perpendicular bisector of the slit arrangement }\)), and \(R\) is the distance from \(P\) to the most distant slit. In this problem, assume that \(R\) is much larger than \(d .\) (b) To carry out the sum in part \((a),\) it is convenient to use the complex-number relationship $$ e^{i k}=\cos z+i \sin z $$ where \(i=\sqrt{-1}\) . In this expression, \(\cos z\) is the real part of the complex number \(e^{i k},\) and \(\sin z\) is its imaginary part. Show that the electric field \(E_{P}(t)\) is equal to the real part of the complex quantity $$ \sum_{n=0}^{N-1} E_{0} e^{i(k R-\omega+n \phi)} $$ (c) Using the properties of the exponential function that \(e^{A} e^{B}=e^{(A+B)}\) and \(\left(e^{A}\right)^{n}=e^{n A},\) show that the sum in part \((b)\) can be written as $$ E_{0}\left(\frac{e^{i N \phi}-1}{e^{i \phi}-1}\right) e^{i(k R-\omega t)}=E_{0}\left(\frac{e^{i N \phi / 2}-e^{-i N \phi / 2}}{e^{i \phi / 2}-e^{-i \phi / 2}}\right) e^{i(k R-\omega t+(N-1) \phi / 2]} $$ Then, using the relationship \(e^{i k}=\cos z+i \sin z,\) show that the (real) electric field at point \(P\) is $$ E_{p}(t)=\left[E_{0} \frac{\sin (N \phi / 2)}{\sin (\phi / 2)}\right] \cos [k R-\omega t+(N-1) \phi / 2] $$ The quantity in the first square brackets in this expression is the amphitude of the electric field at \(P .\) (d) Use the result for the electric-field amplitude in part (c) to show that the intensity at an angle \(\theta\) is $$ I=I_{0}\left[\frac{\sin (N \phi / 2)}{\sin (\phi / 2)}\right]^{2} $$ where \(I_{0}\) is the maximum intensity for an individual slit. (e) Check the result in part (d) for the case \(N=2\) . It will help to recall that \(\sin 2 A=2 \sin A \cos A\) . Explain why your result differs from Eq. \((35.10),\) the expression for the intensity in two-source interference, by a factor of \(4 .\) (Hint: Is \(I_{0}\) defined in the same way in both expressions?)
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