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Deck 17: Sound

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Question
A (point-source) loudspeaker produces an average intensity of 56.8 W/m 22 at two meters away. The output power of the loudspeaker is

A) 2900 W.
B) 1200 W.
C) 710 W.
D) 580 W.
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Question
A listener records a sound intensity of 12 W/m 22 from a 250-W loudspeaker. The loudspeaker emits sound uniformly in all directions. The distance from the loudspeaker to the listener is

A) 2.6 m.
B) 5.2 m.
C) 1.3 m.
D) 4.1 m.
Question
The sound intensity of a 100-W point-source loudspeaker at a distance of one meter is

A) 32 W/m 22
B) 18 W/m 22
C) 26 W/m 22
D) 8.0 W/m 22
Question
The intensity level of a 0.5-W/m 22 signal is

A) 270 dB.
B) 150 dB.
C) 117 dB.
D) 88 dB.
Question
Consider a 55-dB intensity level. The corresponding intensity in W/m 22 is

A) 5.44×1075.44 \times 10 ^ { - 7 } W/m 22
B) 3.16×1073.16 \times 10 ^ { - 7 } W/m 22
C) 7.14×1077.14 \times 10 ^ { - 7 } W/m 22
D) 2.71×1072.71 \times 10 ^ { - 7 } W/m 22
Question
Consider a listener who is a distance xx from a loudspeaker. If the listener moves in so that her distance is now x/2x / 2 from the loudspeaker, by what factor will the intensity of the sound increase?

A) 2
B) 3
C) 1.5
D) 4
Question
The intensity of sound (W/m 22 ) varies as

A) the distance squared.
B) 1 over the distance.
C) 1 over the distance squared.
D) the distance.
Question
The intensity of sound (W/m 22 ) varies as

A) the power squared.
B) 1 over the power.
C) 1 over the power squared.
D) the power.
Question
A person fires a pistol near the opening of a deep vertical well. Half a second later, the person hears the echo of the pistol firing. How deep is the well? (Use 344 m/s for the speed of sound.)

A) 168 m
B) 120 m
C) 98 m
D) 86 m
Question
The difference in intensity level (dB) between a single trumpet and two trumpets is

A) 3 dB.
B) 0 dB.
C) 2 dB.
D) none of the above.
Question
The wavelength of a 1000-Hz tone is (use 344 m/s for the speed of sound)

A) 3.1 m.
B) 4.5 m.
C) 34 cm.
D) 82 cm.
Question
A parked police car turns on its siren of 500 Hz. A thief in a car drives away from the parked police car at 31 m/s. The frequency of the siren as heard by the thief is (use 344 m/s for the speed of sound)

A) 455 Hz.
B) 465 Hz.
C) 530 Hz.
D) 545 Hz.
Question
Two cars travel in a straight line at the same speed; one car is ahead of the other. The car in the front blares its horn. The frequency as heard by the driver in the car behind

A) is higher.
B) is the same.
C) is lower.
D) cannot be determined.
Question
A stationary siren blares at 200 Hz. A person traveling in a car at 40 m/s toward the siren hears the siren at a frequency of (use 344 m/s for the speed of sound)

A) 185 Hz.
B) 191 Hz.
C) 223 Hz.
D) 245 Hz.
Question
A truck travels toward you blaring its horn; the frequency you hear is 76 Hz. Moments later the truck passes you, and now you hear the horn at 65 Hz as it travels away. If the speed of sound is 344 m/s, the true (stationary) frequency of the horn is

A) 70 Hz.
B) 72 Hz.
C) 68 Hz.
D) 66 Hz.
Question
A police car sounds its siren, which has a true frequency of 600 Hz, as it leaves the police station. If the police car is traveling at 35 m/s away from the station, the frequency of the siren as heard by listeners back at the station is (use 344 m/s for the speed of sound)

A) 668 Hz.
B) 545 Hz.
C) 621 Hz.
D) 582 Hz.
Question
The Mach half-angle for a jet traveling at exactly Mach 1 ( Vjet=vV _ { j e t } = v ) is

A) 90º.
B) 0º.
C) 45º.
D) 30º.
Question
The Mach half-angle for a jet traveling at exactly Mach 2 ( Vjet =2vV _ { \text {jet } } = 2 v ) is

A) 90º.
B) 0º.
C) 45º.
D) 30º.
Question
As the velocity of a jet approaches infinity, the Mach half-angle becomes

A) 90º.
B) 0º.
C) 45º.
D) 30º.
Question
Two cars approach each other at the same speed. One driver hears the 500-Hz horn from the other car at a frequency of 600 Hz. The speed of the cars is

A) 27 m/s.
B) 31 m/s.
C) 29 m/s.
D) 33 m/s.
Question
The intensity of sound when integrated over any Gaussian surface ( IdA\int I d A ) that encloses the source yields

A) a conserved quantity.
B) the pressure.
C) a nonconserved quantity.
D) none of the above.
Question
The intensity of sound when integrated over any Gaussian surface ( IdA\int I d A ) that encloses the source yields

A) the energy.
B) the pressure.
C) the power.
D) none of the above.
Question
You are in a dark cave; suddenly you hear screeching sounds that are increasing in pitch. From this you discern that something is

A) coming toward you.
B) going away from you.
C) remaining stationary.
D) none of the above.
Question
If the pitch of the sound is increasing, then the wavelength

A) is increasing.
B) is decreasing.
C) is remaining constant.
D) cannot be determined.
Question
For any sound wave traveling in a medium, as the frequency is increased, the following remains constant:

A) Wavelength
B) Pitch
C) Velocity
D) None of the above
Question
The speed of sound in air v depends on the air pressure p and the air density as

A) νpρ\nu \propto \sqrt { p \rho }
B) v1pρv \propto \sqrt { \frac { 1 } { p \rho } }
C) vpρv \propto \sqrt { \frac { p } { \rho } }
D) vρpv \propto \sqrt { \frac { \rho } { p } }
Question
The speed of water waves in deep water depends on the two parameters

A) gravity and wavelength.
B) gravity and water depth.
C) wavelength and water depth.
D) none of the above.
Question
The speed of water waves in shallow water depends on the two parameters

A) gravity and wavelength.
B) gravity and water depth.
C) wavelength and water depth.
D) none of the above.
Question
Audible sound waves have wavelengths in air on the order of

A) a few microns to a few millimeters.
B) a few inches to a few feet.
C) a few tenths of miles to a few miles.
D) a few hundred miles to a few thousand miles.
Question
The speed of sound in air (in meters per second) is on the order of

A) 0003.
B) 0030.
C) 0300
D) 3000
Question
Diffraction is observed around an obstacle of size \approx 20 λ\lambda . If the obstacle is reduced in size to \approx 2 λ\lambda , the diffraction effect

A) increases.
B) remains unchanged.
C) decreases.
D) none of the above.
Question
All of the following "pairs" are measured or expressed in terms of a logarithmic scale except

A) intensity level-decibel.
B) musical scale-octave.
C) Richter scale-magnitude.
D) none of the above.
Question
A sonic boom can be heard by a listener

A) only at (or in the vicinity of) the time when the speed of the object reaches the speed of sound in the medium.
B) The previous answer is basically correct but must be modified to account for the time it takes the sound to reach the listener.
C) whenever the speed of the object is greater than or equal to the speed of sound in the medium.
D) The previous answer is basically correct but must be qualified by stipulating that the listener be at a location where the shock wave passes.
Question
Some musical (wind) instruments are open at both ends. The length Lboth of the instrument required to achieve a specified fundamental frequency (compared to the length Lone of a musical instrument closed at only one end) is

A) Lboth = 2 Lone.
B) 2 Lboth = Lone.
C) Lboth = 4 Lone.
D) 4 Lboth = Lone.
Question
A musical (wind) instrument Iboth is open at both ends. If it has the same fundamental frequency as an instrument Ione that is closed at one end, the numbers of possible audible harmonics for the two instruments are related by

A) nboth > none.
B) nboth = none.
C) nboth < none.
D) none of the above.
Question
A stationary emitter generates a sound at some particular frequency. The frequency detected by a receiver moving away from the emitter at speed vr (< the speed of sound in still air) is roughly the same as if the

A) emitter were to move at the same speed vr away from a stationary receiver.
B) emitter were to move at the same speed vr toward a stationary receiver.
C) receiver were to move at the same speed vr toward a stationary receiver.
D) none of the above.
Question
A stationary emitter generates a sound of frequency VV . The frequency shift δvγ\delta v _ { \gamma } if the receiver is moving at a speed that is not < the speed of sound in still air is related to the frequency shift δve\delta v _ { e } if the emitter moves at precisely the same speed (in the appropriate direction) with respect to a stationary receiver by the relation

A) Vy>VeV _ { y } > V _ { e }
B) Vy=VeV _ { y } = V _ { e }
C) Vy<VeV _ { y } < V _ { e }
D) none of the above.
Question
Confidence in the correctness of the answer for the previous question can be increased by recognizing that

A) if the emitter moves toward the receiver with a speed equal to that of sound, the frequency received is very large indeed.
B) if the receiver moves away from the emitter with a speed equal to that of sound, the frequency received is very small indeed.
C) both of the first two answers are relevant to the choice of the correct answer to the previous question.
D) none of the above.
Question
The angle θ\theta that the wave front of a Mach cone makes with the direction of travel of a supersonic aircraft is related to the speed of sound v and the speed of the supersonic aircraft (emitter) VE by the formula

A) VE = v cos θ\theta
B) v = VE cos θ\theta
C) VE = v sin θ\theta
D) v = VE sin θ\theta
Question
The intensity I of a wave is related to the distance the wave travels by the expression I ? 18 1/r2. The assumptions on which this formula depend include all of the following except

A) the wave energy travels outward into three-dimensional space.
B) the medium is homogeneous.
C) the medium is nonabsorptive.
D) none of the above.
Question
An example of a longitudinal wave associated with earthquakes is

A) an S-wave.
B) a tsunami.
C) a P-wave.
D) a surface wave.
Question
Generally speaking, the speed of sound in solids (vs) is related to the speed of sound in air (va) by the expression

A) vs > va .
B) vs \approx va .
C) vs < va .
D) none of the above.
Question
The primary reason for the correct answer to the previous question is that

A) the restoring force for solids is > the restoring force for air at atmospheric pressure.
B) the density of solids is > the density of air.
C) the effect of the first answer to this question predominates over the effect of the second answer.
D) the effect of the second answer to this question predominates over the effect of the first answer.
Question
An astute physics student is near a train track. As a train speeds by, the perceived frequency of the whistle changes from middle C to the A below middle C. If the initial perceived frequency of the whistle had been an octave above middle C, as the train whizzed by the frequency would have changed to

A) the A above middle C.
B) a frequency > the A above middle C.
C) a frequency < the A above middle C.
D) none of the above.
Question
The speed of earthquake waves near the surface of the Earth is on the order of 10 times the speed of sound in air. Periods are on the order of a second. Therefore, the distance between "crests" for these waves is on the order of

A) a fraction of an inch.
B) a foot.
C) several hundred feet.
D) a mile.
Question
The wavelength of tsunamis in midocean is on the order of several hundred miles. The speed of tsunami waves near the middle of the ocean is on the order of the speed of sound in air. Therefore, the time between successive crests for a ship in midocean that encounters a tsunami is on the order of

A) a day.
B) an hour.
C) a minute.
D) a second.
Question
The wavelength of tsunamis in midocean is on the order of several hundred miles. The speed of tsunami waves where the ocean is a few miles deep is on the order of the speed of sound in air. As the wave approaches land, its amplitude must

A) increase modestly.
B) increase dramatically.
C) decrease modestly.
D) decrease dramatically.
Question
The explanation for the correct answer to the previous question is that

A) the frequency of the wave changes.
B) the energy of the wave changes.
C) the speed of the wave changes.
D) none of the above.
Question
Under ideal conditions, if a receiver and an emitter are both at rest with respect to the ground and a wind is blowing from receiver to emitter, the received frequency VyV _ { y } will be related to the emitted frequency VEV _ { E } by the expression

A) Vy>VEV _ { y } > V _ { E }
B) Vy=VEV _ { y } = V _ { E }
C) Vy<VEV _ { y } < V _ { E }
D) none of the above.
Question
Under ideal conditions for sound waves, if a receiver is moving perpendicular to the line separating the receiver from an emitter, the received frequency VyV _ { y } will be related to the emitted frequency VEV _ { E } by the expression

A) Vy>VEV _ { y } > V _ { E }
B) Vy=VEV _ { y } = V _ { E }
C) Vy<VEV _ { y } < V _ { E }
D) none of the above.
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Deck 17: Sound
1
A (point-source) loudspeaker produces an average intensity of 56.8 W/m 22 at two meters away. The output power of the loudspeaker is

A) 2900 W.
B) 1200 W.
C) 710 W.
D) 580 W.
2900 W.
2
A listener records a sound intensity of 12 W/m 22 from a 250-W loudspeaker. The loudspeaker emits sound uniformly in all directions. The distance from the loudspeaker to the listener is

A) 2.6 m.
B) 5.2 m.
C) 1.3 m.
D) 4.1 m.
1.3 m.
3
The sound intensity of a 100-W point-source loudspeaker at a distance of one meter is

A) 32 W/m 22
B) 18 W/m 22
C) 26 W/m 22
D) 8.0 W/m 22
8.0 W/m 22
4
The intensity level of a 0.5-W/m 22 signal is

A) 270 dB.
B) 150 dB.
C) 117 dB.
D) 88 dB.
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k this deck
5
Consider a 55-dB intensity level. The corresponding intensity in W/m 22 is

A) 5.44×1075.44 \times 10 ^ { - 7 } W/m 22
B) 3.16×1073.16 \times 10 ^ { - 7 } W/m 22
C) 7.14×1077.14 \times 10 ^ { - 7 } W/m 22
D) 2.71×1072.71 \times 10 ^ { - 7 } W/m 22
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k this deck
6
Consider a listener who is a distance xx from a loudspeaker. If the listener moves in so that her distance is now x/2x / 2 from the loudspeaker, by what factor will the intensity of the sound increase?

A) 2
B) 3
C) 1.5
D) 4
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7
The intensity of sound (W/m 22 ) varies as

A) the distance squared.
B) 1 over the distance.
C) 1 over the distance squared.
D) the distance.
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k this deck
8
The intensity of sound (W/m 22 ) varies as

A) the power squared.
B) 1 over the power.
C) 1 over the power squared.
D) the power.
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9
A person fires a pistol near the opening of a deep vertical well. Half a second later, the person hears the echo of the pistol firing. How deep is the well? (Use 344 m/s for the speed of sound.)

A) 168 m
B) 120 m
C) 98 m
D) 86 m
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10
The difference in intensity level (dB) between a single trumpet and two trumpets is

A) 3 dB.
B) 0 dB.
C) 2 dB.
D) none of the above.
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k this deck
11
The wavelength of a 1000-Hz tone is (use 344 m/s for the speed of sound)

A) 3.1 m.
B) 4.5 m.
C) 34 cm.
D) 82 cm.
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12
A parked police car turns on its siren of 500 Hz. A thief in a car drives away from the parked police car at 31 m/s. The frequency of the siren as heard by the thief is (use 344 m/s for the speed of sound)

A) 455 Hz.
B) 465 Hz.
C) 530 Hz.
D) 545 Hz.
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13
Two cars travel in a straight line at the same speed; one car is ahead of the other. The car in the front blares its horn. The frequency as heard by the driver in the car behind

A) is higher.
B) is the same.
C) is lower.
D) cannot be determined.
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14
A stationary siren blares at 200 Hz. A person traveling in a car at 40 m/s toward the siren hears the siren at a frequency of (use 344 m/s for the speed of sound)

A) 185 Hz.
B) 191 Hz.
C) 223 Hz.
D) 245 Hz.
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15
A truck travels toward you blaring its horn; the frequency you hear is 76 Hz. Moments later the truck passes you, and now you hear the horn at 65 Hz as it travels away. If the speed of sound is 344 m/s, the true (stationary) frequency of the horn is

A) 70 Hz.
B) 72 Hz.
C) 68 Hz.
D) 66 Hz.
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16
A police car sounds its siren, which has a true frequency of 600 Hz, as it leaves the police station. If the police car is traveling at 35 m/s away from the station, the frequency of the siren as heard by listeners back at the station is (use 344 m/s for the speed of sound)

A) 668 Hz.
B) 545 Hz.
C) 621 Hz.
D) 582 Hz.
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k this deck
17
The Mach half-angle for a jet traveling at exactly Mach 1 ( Vjet=vV _ { j e t } = v ) is

A) 90º.
B) 0º.
C) 45º.
D) 30º.
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18
The Mach half-angle for a jet traveling at exactly Mach 2 ( Vjet =2vV _ { \text {jet } } = 2 v ) is

A) 90º.
B) 0º.
C) 45º.
D) 30º.
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19
As the velocity of a jet approaches infinity, the Mach half-angle becomes

A) 90º.
B) 0º.
C) 45º.
D) 30º.
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20
Two cars approach each other at the same speed. One driver hears the 500-Hz horn from the other car at a frequency of 600 Hz. The speed of the cars is

A) 27 m/s.
B) 31 m/s.
C) 29 m/s.
D) 33 m/s.
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21
The intensity of sound when integrated over any Gaussian surface ( IdA\int I d A ) that encloses the source yields

A) a conserved quantity.
B) the pressure.
C) a nonconserved quantity.
D) none of the above.
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22
The intensity of sound when integrated over any Gaussian surface ( IdA\int I d A ) that encloses the source yields

A) the energy.
B) the pressure.
C) the power.
D) none of the above.
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23
You are in a dark cave; suddenly you hear screeching sounds that are increasing in pitch. From this you discern that something is

A) coming toward you.
B) going away from you.
C) remaining stationary.
D) none of the above.
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k this deck
24
If the pitch of the sound is increasing, then the wavelength

A) is increasing.
B) is decreasing.
C) is remaining constant.
D) cannot be determined.
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25
For any sound wave traveling in a medium, as the frequency is increased, the following remains constant:

A) Wavelength
B) Pitch
C) Velocity
D) None of the above
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26
The speed of sound in air v depends on the air pressure p and the air density as

A) νpρ\nu \propto \sqrt { p \rho }
B) v1pρv \propto \sqrt { \frac { 1 } { p \rho } }
C) vpρv \propto \sqrt { \frac { p } { \rho } }
D) vρpv \propto \sqrt { \frac { \rho } { p } }
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27
The speed of water waves in deep water depends on the two parameters

A) gravity and wavelength.
B) gravity and water depth.
C) wavelength and water depth.
D) none of the above.
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k this deck
28
The speed of water waves in shallow water depends on the two parameters

A) gravity and wavelength.
B) gravity and water depth.
C) wavelength and water depth.
D) none of the above.
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29
Audible sound waves have wavelengths in air on the order of

A) a few microns to a few millimeters.
B) a few inches to a few feet.
C) a few tenths of miles to a few miles.
D) a few hundred miles to a few thousand miles.
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30
The speed of sound in air (in meters per second) is on the order of

A) 0003.
B) 0030.
C) 0300
D) 3000
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31
Diffraction is observed around an obstacle of size \approx 20 λ\lambda . If the obstacle is reduced in size to \approx 2 λ\lambda , the diffraction effect

A) increases.
B) remains unchanged.
C) decreases.
D) none of the above.
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k this deck
32
All of the following "pairs" are measured or expressed in terms of a logarithmic scale except

A) intensity level-decibel.
B) musical scale-octave.
C) Richter scale-magnitude.
D) none of the above.
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Unlock Deck
k this deck
33
A sonic boom can be heard by a listener

A) only at (or in the vicinity of) the time when the speed of the object reaches the speed of sound in the medium.
B) The previous answer is basically correct but must be modified to account for the time it takes the sound to reach the listener.
C) whenever the speed of the object is greater than or equal to the speed of sound in the medium.
D) The previous answer is basically correct but must be qualified by stipulating that the listener be at a location where the shock wave passes.
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k this deck
34
Some musical (wind) instruments are open at both ends. The length Lboth of the instrument required to achieve a specified fundamental frequency (compared to the length Lone of a musical instrument closed at only one end) is

A) Lboth = 2 Lone.
B) 2 Lboth = Lone.
C) Lboth = 4 Lone.
D) 4 Lboth = Lone.
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35
A musical (wind) instrument Iboth is open at both ends. If it has the same fundamental frequency as an instrument Ione that is closed at one end, the numbers of possible audible harmonics for the two instruments are related by

A) nboth > none.
B) nboth = none.
C) nboth < none.
D) none of the above.
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36
A stationary emitter generates a sound at some particular frequency. The frequency detected by a receiver moving away from the emitter at speed vr (< the speed of sound in still air) is roughly the same as if the

A) emitter were to move at the same speed vr away from a stationary receiver.
B) emitter were to move at the same speed vr toward a stationary receiver.
C) receiver were to move at the same speed vr toward a stationary receiver.
D) none of the above.
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37
A stationary emitter generates a sound of frequency VV . The frequency shift δvγ\delta v _ { \gamma } if the receiver is moving at a speed that is not < the speed of sound in still air is related to the frequency shift δve\delta v _ { e } if the emitter moves at precisely the same speed (in the appropriate direction) with respect to a stationary receiver by the relation

A) Vy>VeV _ { y } > V _ { e }
B) Vy=VeV _ { y } = V _ { e }
C) Vy<VeV _ { y } < V _ { e }
D) none of the above.
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38
Confidence in the correctness of the answer for the previous question can be increased by recognizing that

A) if the emitter moves toward the receiver with a speed equal to that of sound, the frequency received is very large indeed.
B) if the receiver moves away from the emitter with a speed equal to that of sound, the frequency received is very small indeed.
C) both of the first two answers are relevant to the choice of the correct answer to the previous question.
D) none of the above.
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39
The angle θ\theta that the wave front of a Mach cone makes with the direction of travel of a supersonic aircraft is related to the speed of sound v and the speed of the supersonic aircraft (emitter) VE by the formula

A) VE = v cos θ\theta
B) v = VE cos θ\theta
C) VE = v sin θ\theta
D) v = VE sin θ\theta
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40
The intensity I of a wave is related to the distance the wave travels by the expression I ? 18 1/r2. The assumptions on which this formula depend include all of the following except

A) the wave energy travels outward into three-dimensional space.
B) the medium is homogeneous.
C) the medium is nonabsorptive.
D) none of the above.
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41
An example of a longitudinal wave associated with earthquakes is

A) an S-wave.
B) a tsunami.
C) a P-wave.
D) a surface wave.
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42
Generally speaking, the speed of sound in solids (vs) is related to the speed of sound in air (va) by the expression

A) vs > va .
B) vs \approx va .
C) vs < va .
D) none of the above.
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43
The primary reason for the correct answer to the previous question is that

A) the restoring force for solids is > the restoring force for air at atmospheric pressure.
B) the density of solids is > the density of air.
C) the effect of the first answer to this question predominates over the effect of the second answer.
D) the effect of the second answer to this question predominates over the effect of the first answer.
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44
An astute physics student is near a train track. As a train speeds by, the perceived frequency of the whistle changes from middle C to the A below middle C. If the initial perceived frequency of the whistle had been an octave above middle C, as the train whizzed by the frequency would have changed to

A) the A above middle C.
B) a frequency > the A above middle C.
C) a frequency < the A above middle C.
D) none of the above.
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45
The speed of earthquake waves near the surface of the Earth is on the order of 10 times the speed of sound in air. Periods are on the order of a second. Therefore, the distance between "crests" for these waves is on the order of

A) a fraction of an inch.
B) a foot.
C) several hundred feet.
D) a mile.
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46
The wavelength of tsunamis in midocean is on the order of several hundred miles. The speed of tsunami waves near the middle of the ocean is on the order of the speed of sound in air. Therefore, the time between successive crests for a ship in midocean that encounters a tsunami is on the order of

A) a day.
B) an hour.
C) a minute.
D) a second.
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47
The wavelength of tsunamis in midocean is on the order of several hundred miles. The speed of tsunami waves where the ocean is a few miles deep is on the order of the speed of sound in air. As the wave approaches land, its amplitude must

A) increase modestly.
B) increase dramatically.
C) decrease modestly.
D) decrease dramatically.
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48
The explanation for the correct answer to the previous question is that

A) the frequency of the wave changes.
B) the energy of the wave changes.
C) the speed of the wave changes.
D) none of the above.
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49
Under ideal conditions, if a receiver and an emitter are both at rest with respect to the ground and a wind is blowing from receiver to emitter, the received frequency VyV _ { y } will be related to the emitted frequency VEV _ { E } by the expression

A) Vy>VEV _ { y } > V _ { E }
B) Vy=VEV _ { y } = V _ { E }
C) Vy<VEV _ { y } < V _ { E }
D) none of the above.
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50
Under ideal conditions for sound waves, if a receiver is moving perpendicular to the line separating the receiver from an emitter, the received frequency VyV _ { y } will be related to the emitted frequency VEV _ { E } by the expression

A) Vy>VEV _ { y } > V _ { E }
B) Vy=VEV _ { y } = V _ { E }
C) Vy<VEV _ { y } < V _ { E }
D) none of the above.
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