Question 1

Two harmonic waves are described by     From the choices given, determine the smallest positive value of x (in cm) corresponding to a node of the resultant standing wave.&#10;A) 3&#10;B) 0.25&#10;C) 0&#10;D) 6&#10;E) 1.5

Accepted Answer

0

Question 2

Two tuning forks with frequencies 264 and 262 Hz produce &#34;beats&#34;. What is the beat frequency (in Hz)?&#10;A) 4&#10;B) 2&#10;C) 1&#10;D) 3&#10;E) 0 (no beats are produced)

Accepted Answer

The beat frequency is the absolute difference between the two frequencies, which is |264 Hz - 262 Hz| = 2 Hz.

Question 3

Two harmonic waves are described by     What is the wavelength of the resultant wave?&#10;A) 3 m&#10;B) 2 m&#10;C) 1 m&#10;D) 4 m&#10;E) 6 m

Accepted Answer

1 m

Question 4

Two harmonic waves traveling in opposite directions interfere to produce a standing wave described by y = 4 sin (5x) cos (6t) where x is in m and t is in s. What is the approximate frequency of the interfering waves?

A) 3 Hz
B) 1 Hz
C) 6 Hz
D) 12 Hz
E) 5 Hz

Accepted Answer

The answer of Two harmonic waves traveling in opposite directions...

Question 5

Two harmonic waves are described by     What is the magnitude of the speed (in m/s) of the two traveling waves?&#10;A) 16&#10;B) 4.0&#10;C) 8.0&#10;D) 0.25&#10;E) 2.0

Accepted Answer

The answer of Two harmonic waves are described by ...

Question 6

Two harmonic waves traveling in opposite directions interfere to produce a standing wave described by y = 4 sin (5x) cos (6t) where x is in m and t is in s. What is the approximate frequency of the interfering waves?

A) 3 Hz
B) 1 Hz
C) 6 Hz
D) 12 Hz
E) 5 Hz

Accepted Answer

The speed of the waves can be determined from the wave equation. The general form of a standing wave resulting from the interference of two waves traveling in opposite directions can be given by $y = 2A \sin(kx) \cos(\omega t)$, where $k$ is the wave number and $\omega$ is the angular frequency. The speed $v$ of the waves can be found using the relationship $v = \frac{\omega}{k}$. Given $k = 4 \, \text{m}^{-1}$ and $\omega = 3 \, \text{s}^{-1}$, the speed $v = \frac{3}{4} = 0.75 \, \text{m/s}$.

Question 7

Two harmonic waves are described by     What is the magnitude of the displacement (in cm) of this wave at x = 3 cm and t = 5 sec?&#10;A) 12.0&#10;B) 3.00&#10;C) 6.00&#10;D) 2.25&#10;E) 0

Accepted Answer

The answer of Two harmonic waves are described by ...

Question 8

Two harmonic waves traveling in opposite directions interfere to produce a standing wave described by y = 4 sin (5x) cos (6t) where x is in m and t is in s. What is the approximate frequency of the interfering waves?

A) 3 Hz
B) 1 Hz
C) 6 Hz
D) 12 Hz
E) 5 Hz

Accepted Answer

The distance between the first two antinodes in a standing wave is equal to half the wavelength. The given equation is $y = 2 \sin (\pi x) \cos (3\pi t)$. The spatial part of the wave equation, $\sin (\pi x)$, determines the pattern of nodes and antinodes. The wavelength $\lambda$ can be found from the spatial part's coefficient of $x$, which is $\pi$. Since the general form for a wave is $\sin(kx)$ where $k = \frac{2\pi}{\lambda}$, comparing it to $\sin(\pi x)$ gives $k = \pi = \frac{2\pi}{\lambda}$, solving for $\lambda$ gives $\lambda = 2$ meters. Therefore, the distance between the first two antinodes, which is half the wavelength, is $1$ meter.

Question 9

Two harmonic waves traveling in opposite directions interfere to produce a standing wave described by y = 4 sin (5x) cos (6t) where x is in m and t is in s. What is the approximate frequency of the interfering waves?

A) 3 Hz
B) 1 Hz
C) 6 Hz
D) 12 Hz
E) 5 Hz

Accepted Answer

The wavelength is given by lambda = 2*pi/k, where k is the wave number. The wave number is given by k = 2*pi/lambda. So, lambda = 2*pi/k = 2*pi/(2*pi/3) = 3 m.

Question 10

An organ pipe open at both ends has a radius of 4.0 cm and a length of 6.0 m. What is the frequency (in Hz) of the third harmonic? (Assume the velocity of sound is 344 m/s.)&#10;A) 76&#10;B) 86&#10;C) 54&#10;D) 28&#10;E) 129

Accepted Answer

The answer of An organ pipe open at both ends...

Question 11

A clarinet behaves like a tube closed at one end. If its length is 1.0 m, and the velocity of sound is 344 m/s, what is its fundamental frequency (in Hz)?&#10;A) 264&#10;B) 140&#10;C) 86&#10;D) 440&#10;E) 172

Accepted Answer

The answer of A clarinet behaves like a tube closed...

Question 12

A vertical tube one meter long is open at the top. It is filled with 75 cm of water. If the velocity of sound is 344 m/s, what will the fundamental resonant frequency be (in Hz)?&#10;A) 3.4&#10;B) 172&#10;C) 344&#10;D) 1.7&#10;E) 688

Accepted Answer

The answer of A vertical tube one meter long is...

Question 13

Two harmonic waves are described by     What is the phase (in rad) of the resultant wave when x = t = 0?&#10;A) 3&#10;B) 0&#10;C) 2&#10;D) 1&#10;E) 4

Accepted Answer

The answer of Two harmonic waves are described by ...

Question 14

A length of organ pipe is closed at one end. If the speed of sound is 344 m/s, what length of pipe (in cm) is needed to obtain a fundamental frequency of 50 Hz?&#10;A) 28&#10;B) 86&#10;C) 344&#10;D) 172&#10;E) 688

Accepted Answer

The answer of A length of organ pipe is closed...

Question 15

A string is stretched and fixed at both ends, 200 cm apart. If the density of the string is 0.015 g/cm, and its tension is 600 N, what is the fundamental frequency?&#10;A) 316 Hz&#10;B) 632 Hz&#10;C) 158 Hz&#10;D) 215 Hz&#10;E) 79 Hz

Accepted Answer

The answer of A string is stretched and fixed at...

Question 16

A stretched string is observed to vibrate in three equal segments when driven by a 480 Hz oscillator. What is the fundamental frequency of vibration for this string?&#10;A) 480 Hz&#10;B) 320 Hz&#10;C) 160 Hz&#10;D) 640 Hz&#10;E) 240 Hz

Accepted Answer

The answer of A stretched string is observed to vibrate...

Question 17

Two harmonic waves are described by     What is the amplitude of the resultant wave?&#10;A) 8.0 m&#10;B) 4.3 m&#10;C) 6.0 m&#10;D) 3.2 m&#10;E) 3.0 m

Accepted Answer

The answer of Two harmonic waves are described by ...

Question 18

The path difference between two waves is 5m. If the wavelength of the waves emitted by the two sources is 4m, what is the phase difference (in degrees)?&#10;A) 90&#10;B) 400&#10;C) 1.57&#10;D) 7.85&#10;E) 15

Accepted Answer

The answer of The path difference between two waves is...

Question 19

Two harmonic waves are described by     What is the frequency (in Hz) of the resultant wave?&#10;A) 300&#10;B) 48&#10;C) 8&#10;D) 0.8&#10;E) 150

Accepted Answer

The answer of Two harmonic waves are described by ...

Question 20

A string is stretched and fixed at both ends, 200 cm apart. If the density of the string is 0.015 g/cm, and its tension is 600 N, what is the wavelength (in cm) of the first harmonic?&#10;A) 600&#10;B) 400&#10;C) 800&#10;D) 1 000&#10;E) 200

Accepted Answer

The answer of A string is stretched and fixed at...

Question 21

Which of the following wavelengths could NOT be present as a harmonic on a 2 m long string?&#10;A) 4 m&#10;B) 2 m&#10;C) 1 m&#10;D) 0.89 m&#10;E) 0.5 m

Accepted Answer

The answer of Which of the following wavelengths could NOT...

Question 22

Two identical strings have the same length and same mass per unit length. String B is stretched with four times as great a tension as that applied to string A. Which statement is correct for all n harmonics on the two strings, n = 1, 2, 3...?

A)

<strong>Two identical strings have the same length and same mass per unit length. String B is stretched with four times as great a tension as that applied to string A. Which statement is correct for all n harmonics on the two strings, n = 1, 2, 3...?</strong> A) . B) . C) . D) f<sub>n,B</sub> = 2f<sub>n,A</sub>. E) f<sub>n,B</sub> = 4f<sub>n,A</sub>. <div style=padding-top: 35px>

.
B)

.
C)

.
D) f_n,B = 2f_n,A.
E) f_n,B = 4f_n,A.

Accepted Answer

The answer of Two identical strings have the same length...

Question 23

In a standing wave, not necessarily at the fundamental frequency, on a string of length L, the distance between nodes is&#10;A) &#955;/4.&#10;B) &#955;/2.&#10;C) &#955;.&#10;D) L/4.&#10;E) L/2.

Accepted Answer

The answer of In a standing wave, not necessarily at...

Question 24

The superposition of two waves,   and   , results in a wave with a wavelength of&#10;A)&#10;  m.&#10;B) 2 m.&#10;C) &#960; m.&#10;D) 4 m.&#10;E) 4&#960; m.

Accepted Answer

The answer of The superposition of two waves,  ...

Question 25

As shown below, a garden room has three walls, a floor and a roof, but is open to the garden on one side. The wall widths are L and w. The roof height is h. When traveling sound waves enter the room, standing sound waves can be present in the room if the wavelength of the standing waves is

A)

<strong>As shown below, a garden room has three walls, a floor and a roof, but is open to the garden on one side. The wall widths are L and w. The roof height is h. When traveling sound waves enter the room, standing sound waves can be present in the room if the wavelength of the standing waves is </strong> A) , where n is a positive integer. B) , where n is an odd integer. C) , where n is an even integer. D) in all cases listed above. E) given by (a) or (b) above, but not by (c). <div style=padding-top: 35px>

, where n is a positive integer.
B)

, where n is an odd integer.
C)

, where n is an even integer.
D) in all cases listed above.
E) given by (a) or (b) above, but not by (c).

Accepted Answer

The answer of As shown below, a garden room has...

Question 26

Transverse waves y₁ = A₁ sin(k₁x − ω₁t) and y₂ = A₂ sin(k₂x − ω₂t), with A₂ > A₁, start at opposite ends of a long rope when t = 0. The magnitude of the maximum displacement, y, of the rope at any point is

A) A₁ − A₂.
B) A₂ − A₁.
C) A₁ + A₂.
D)

<strong>Transverse waves y<sub>1</sub> = A<sub>1</sub> sin(k<sub>1</sub>x − ω<sub>1</sub>t) and y<sub>2</sub> = A<sub>2</sub> sin(k<sub>2</sub>x − ω<sub>2</sub>t), with A<sub>2</sub> > A<sub>1</sub>, start at opposite ends of a long rope when t = 0. The magnitude of the maximum displacement, y, of the rope at any point is</strong> A) A<sub>1</sub> − A<sub>2</sub>. B) A<sub>2</sub> − A<sub>1</sub>. C) A<sub>1</sub> + A<sub>2</sub>. D) . E) . <div style=padding-top: 35px>

.
E)

.

Accepted Answer

The answer of Transverse waves y₁ = A₁ sin(k₁x −...

Question 27

Two waves are described by y₁ = 6 cos 180t and y₂ = 6 cos 186t, (both in meters).
What effective frequency does the resultant vibration have at a point?

A) 92 Hz
B) 183 Hz
C) 6 Hz
D) 3 Hz
E) 366 Hz

Accepted Answer

The answer of Two waves are described by y₁ =...

Question 28

The superposition of two waves,   and   , results in a wave with a frequency of&#10;A) 85 Hz.&#10;B) 170 Hz.&#10;C) 85&#960; Hz.&#10;D) 340 Hz.&#10;E) 170&#960; Hz.

Accepted Answer

The answer of The superposition of two waves,  ...

Question 29

Two point sources emit sound waves of 1.0-m wavelength. The sources, 2.0 m apart, as shown below, emit waves which are in phase with each other at the instant of emission. Where, along the line between the sources, are the waves out of phase with each other by π radians?

A) x = 0, 1.0 m, 2.0 m
B) x = 0.50 m, 1.5 m
C) x = 0.50 m, 1.0 m, 1.5 m
D) x = 0.75 m, 1.25 m
E) x = 0.25 m, 0.75 m, 1.25 m, 1.75 m

Accepted Answer

The answer of Two point sources emit sound waves of...

Question 30

Which of the following frequencies could NOT be present as a standing wave in a 2m long organ pipe open at both ends? The fundamental frequency is 85 Hz.&#10;A) 85 Hz.&#10;B) 170 Hz.&#10;C) 255 Hz.&#10;D) 340 Hz.&#10;E) 382 Hz.

Accepted Answer

The answer of Which of the following frequencies could NOT...

Question 31

Two strings are respectively 1.00 m and 2.00 m long. Which of the following wavelengths, in meters, could represent harmonics present on both strings?&#10;A) 0.800, 0.670, 0.500&#10;B) 1.33, 1.00, 0.500&#10;C) 2.00, 1.00, 0.500&#10;D) 2.00, 1.33, 1.00&#10;E) 4.00, 2.00, 1.00

Accepted Answer

The answer of Two strings are respectively 1.00 m and...

Question 32

Two speakers in an automobile emit sound waves that are in phase at the speakers. One speaker is 40 cm ahead of and 30 cm to the left of the driver's left ear. The other speaker is 50 cm ahead of and 120 cm to the right of the driver's right ear. Which of the following wavelengths is(are) in phase at the left ear for the speaker on the left and the right ear for the speaker on the right?

A) 10 cm
B) 20 cm
C) 650 cm
D) All of the wavelengths listed above.
E) Only the wavelengths listed in (a) and (b).

Accepted Answer

The answer of Two speakers in an automobile emit sound...

Question 33

An organ pipe open at both ends is 1.5 m long. A second organ pipe that is closed at one end and open at the other is 0.75 m long. The speed of sound in the room is 330 m/s. Which of the following sets of frequencies consists of frequencies which can be produced by both pipes?

A) 110 Hz, 220 Hz, 330 Hz
B) 220 Hz, 440 Hz, 660 Hz
C) 110 Hz, 330 Hz, 550 Hz
D) 330 Hz, 440 Hz, 550 Hz
E) 220 Hz, 660 Hz, 1 100 Hz

Accepted Answer

The answer of An organ pipe open at both ends...

Question 34

A very long string is tied to a rigid wall at one end while the other end is attached to a simple harmonic oscillator. Which of the following can be changed by changing the frequency of the oscillator?

A) The speed of the waves traveling along the string.
B) The tension in the string.
C) The wavelength of the waves on the string.
D) All of the above.
E) None of the above.

Accepted Answer

The answer of A very long string is tied to...

Question 35

The superposition of two waves,   and   , results in a wave with a phase angle of&#10;A) 0 rad.&#10;B) 0.5 rad.&#10;C)&#10;  rad.&#10;D)&#10;  rad.&#10;E) &#960; rad.

Accepted Answer

The answer of The superposition of two waves,  ...

Question 36

An observer stands 3 m from speaker A and 4 m from speaker B. Both speakers, oscillating in phase, produce 170 Hz waves. The speed of sound in air is 340 m/s. What is the phase difference (in radians) between the waves from A and B at the observer's location, point P?

A) 0
B)

<strong>An observer stands 3 m from speaker A and 4 m from speaker B. Both speakers, oscillating in phase, produce 170 Hz waves. The speed of sound in air is 340 m/s. What is the phase difference (in radians) between the waves from A and B at the observer's location, point P? </strong> A) 0 B) C) π D) 2π E) 4π <div style=padding-top: 35px>

C) π
D) 2π
E) 4π

Accepted Answer

The answer of An observer stands 3 m from speaker...

Question 37

Which of the following wavelengths could NOT be present as a standing wave in a 2 m long organ pipe open at both ends?&#10;A) 4 m&#10;B) 2 m&#10;C) 1 m&#10;D) 0.89 m&#10;E) 0.5 m

Accepted Answer

The answer of Which of the following wavelengths could NOT...

Question 38

Two instruments produce a beat frequency of 5 Hz. If one has a frequency of 264 Hz, what could be the frequency of the other instrument?&#10;A) 269 Hz&#10;B) 254 Hz&#10;C) 264 Hz&#10;D) 5 Hz&#10;E) 274 Hz

Accepted Answer

The answer of Two instruments produce a beat frequency of...

Question 39

The superposition of two waves   and   at the location x = 0 in space results in&#10;A) beats at a beat frequency of 3 Hz.&#10;B) a pure tone at a frequency of 153 Hz.&#10;C) a pure tone at a frequency of 156 Hz.&#10;D) beats at a beat frequency of 6 Hz in a 153 Hz tone.&#10;E) a tone at a frequency of 156 Hz, as well as beats at a beat frequency of 6 Hz in a 153 Hz tone.

Accepted Answer

The answer of The superposition of two waves  ...

Question 40

Two waves are described by y₁ = 6 cos 180t and y₂ = 6 cos 186t, (both in meters).
With what angular frequency does the maximum amplitude of the resultant wave vary with time?

A) 366 rad/s
B) 6 rad/s
C) 3 rad/s
D) 92 rad/s
E) 180 rad/s

Accepted Answer

The answer of Two waves are described by y₁ =...

Question 41

Find the frequencies of the first three harmonics of a 1.0-m long string which has a mass per unit length of 2.0 × 10−³ kg/m and a tension of 80 N when both ends are fixed in place.

Accepted Answer

The answer of Find the frequencies of the first three...

Question 42

A harmonic longitudinal wave propagating down a tube filled with a compressible gas has the form s(x, t) = s_m cos (kx − ωt). Its velocity can be obtained from A) ω/k B) k/ω C) k D) ω E) ωk

Accepted Answer

The answer of A harmonic longitudinal wave propagating down a...

Question 43

Tuning forks #1, #2, and #3 each have slightly different frequencies.When #1 and #2 are sounded together, a beat frequency of 3 Hz results. When #2 and #3 are sounded together, a beat frequency of 5 Hz results. If the frequency of #1 is 100 Hz, which of the following cannot be the frequency of #3?

A) 92 Hz
B) 95 Hz
C) 98 Hz
D) 102 Hz
E) 108 Hz

Accepted Answer

The answer of Tuning forks #1, #2, and #3 each...

Question 44

The figure below shows the positions of particles in a longitudinal standing wave. One quarter period later the particle distribution is shown in  &#10;A)&#10; &#10;B)&#10; &#10;C)&#10; &#10;D)&#10; &#10;E)&#10;

Accepted Answer

The answer of The figure below shows the positions of...

Question 45

Exhibit 18-1&#10;The figure below shows wave crests after a stone is thrown into a pond.   Use this exhibit to answer the following question(s).&#10;Refer to Exhibit 18-1. The phase difference in radians between points A and B is&#10;A) 0.&#10;B)&#10;  .&#10;C)&#10;  .&#10;D) &#960;.&#10;E)&#10;  .

Accepted Answer

The answer of Exhibit 18-1&#10;The figure below shows wave crests...

Question 46

Two organ pipes, a pipe of fundamental frequency 440 Hz, closed at one end, and a pipe of fundamental frequency 660 Hz, open at both ends, produce overtones. Which choice below correctly describes overtones present in both pipes?

A) After the first overtone of each pipe, every second overtone of the first pipe matches every second overtone of the second pipe.
B) After the first overtone of each pipe, every second overtone of the first pipe matches every third overtone of the second pipe.
C) After the first overtone of each pipe, every third overtone of the first pipe matches every second overtone of the second pipe.
D) After the first overtone of each pipe, every second overtone of the first pipe matches every fourth overtone of the second pipe.
E) After the first overtone of each pipe, every third overtone of the first pipe matches every fourth overtone of the second pipe.

Accepted Answer

The answer of Two organ pipes, a pipe of fundamental...

Question 47

Two pulses are traveling towards each other at 10 cm/s on a long string at t = 0 s, as shown below.   Which diagram below correctly shows the shape of the string at 0.5 s?&#10;A)&#10; &#10;B)&#10; &#10;C)&#10; &#10;D)&#10; &#10;E)&#10;

Accepted Answer

The answer of Two pulses are traveling towards each other...

Question 48

A string with a fixed frequency vibrator at one end is subjected to varying tensions. When the tension is 20 N, a resonance with 3 antinodes results. What tension would cause a resonance with 2 antinodes in this string?

A) 30 N
B) 45 N
C) 80 N
D) 8.9 N
E) 13 N

Accepted Answer

The answer of A string with a fixed frequency vibrator...

Question 49

Superposition of waves can occur&#10;A) in transverse waves.&#10;B) in longitudinal waves.&#10;C) in sinusoidal waves.&#10;D) in all of the above.&#10;E) only in (a) and (c) above.

Accepted Answer

The answer of Superposition of waves can occur&#10;A) in transverse...

Question 50

A string with a fixed frequency vibrator at one end is undergoing resonance with 4 antinodes when under tension T₁. When the tension is slowly increased the resonance condition disappears until tension T₂ is reached, there being no resonances occurring between these two tensions. How many antinodes are there in this new resonance? A) 3 B) 4, since all resonances in this situation have the same number of nodes C) 5 D) 2, since resonances only involve whole wavelengths E) 6, since resonances only involve whole wavelength

Accepted Answer

The answer of A string with a fixed frequency vibrator...

Question 51

Exhibit 18-1&#10;The figure below shows wave crests after a stone is thrown into a pond.   Use this exhibit to answer the following question(s).&#10;Refer to Exhibit 18-1. The phase difference in radians between points A and C is&#10;A) 0.&#10;B)&#10;  .&#10;C) &#960;.&#10;D)&#10;  .&#10;E) 2&#960;

Accepted Answer

The answer of Exhibit 18-1&#10;The figure below shows wave crests...

Question 52

Two ropes are spliced together as shown.   A short time after the incident pulse shown in the diagram reaches the splice, the rope's appearance will be that in&#10;A)&#10; &#10;B)&#10; &#10;C)&#10; &#10;D)&#10; &#10;E)&#10;

Accepted Answer

The answer of Two ropes are spliced together as shown....

Question 53

Drummers like to have high-pitched cymbals that vibrate at high frequencies. To obtain the highest frequencies, a cymbal of a fixed size should be made of a material&#10;A) with a low Young's modulus and a low density.&#10;B) with a low Young's modulus and a high density.&#10;C) with a high Young's modulus and a low density.&#10;D) with a high Young's modulus and a high density.&#10;E) composed of a metal-plastic laminate.

Accepted Answer

The answer of Drummers like to have high-pitched cymbals that...

Question 54

Two ropes are spliced together as shown.   A short time after the incident pulse shown in the diagram reaches the splice, the rope's appearance will be that in&#10;A)&#10; &#10;B)&#10; &#10;C)&#10; &#10;D)&#10; &#10;E)&#10;

Accepted Answer

The answer of Two ropes are spliced together as shown....

Question 55

A steel wire in a piano has a length of 0.700 m and a mass of 4.30 grams. To what tension must this wire be stretched to make the fundamental frequency correspond to middle C, (f_c = 261.6 Hz)?

Accepted Answer

The answer of A steel wire in a piano has...

Question 56

When two organ pipes each closed at one end sound a perfect fifth, such as two notes with fundamental frequencies at 440 Hz and 660 Hz, both pipes produce overtones. Which choice below correctly describes overtones present in both pipes?&#10;A) 440, 880 and 1 320 Hz.&#10;B) 660, 1 320 and 1 980 Hz.&#10;C) 880, 1 320 and 1 760 Hz.&#10;D) 1 320, 2 640 and 3 960 Hz.&#10;E) They have no overtones in common.

Accepted Answer

The answer of When two organ pipes each closed at...

Question 57

When two organ pipes open at both ends sound a perfect fifth, such as two notes with fundamental frequencies at 440 Hz and 660 Hz, both pipes produce overtones. Which choice below correctly describes overtones present in both pipes?&#10;A) 440, 880 and 1 320 Hz.&#10;B) 660, 1 320 and 1 980 Hz.&#10;C) 880, 1 320 and 1 760 Hz.&#10;D) 1 320, 2 640 and 3 960 Hz.&#10;E) They have no overtones in common.

Accepted Answer

The answer of When two organ pipes open at both...

Question 58

A fire engine approaches a wall at 5 m/s while the siren emits a tone of 500 Hz frequency. At the time, the speed of sound in air is 340 m/s. How many beats per second do the people on the fire engine hear?&#10;A) 0&#10;B) 15&#10;C) 29&#10;D) 63&#10;E) 250

Accepted Answer

The answer of A fire engine approaches a wall at...

Question 59

Exhibit 18-1&#10;The figure below shows wave crests after a stone is thrown into a pond.   Use this exhibit to answer the following question(s).&#10;Refer to Exhibit 18-1. The phase difference in radians between points A and D is&#10;A) &#960;.&#10;B) 2&#960;.&#10;C) 3&#960;.&#10;D) 4&#960;.&#10;E) 5&#960;.

Accepted Answer

The answer of Exhibit 18-1&#10;The figure below shows wave crests...

Question 60

A student wants to establish a standing wave on a wire 1.8 m long clamped at both ends. The wave speed is 540 m/s. What is the minimum frequency she should apply to set up standing waves?

Accepted Answer

The answer of A student wants to establish a standing...

Question 61

A boat sounds a fog horn on a day when both the sea water and the air temperature are 25.0&#176; C. The speed of sound in sea water is 1 533 m/s. How much earlier (in s) does a dolphin 1 000 m from the source hear the sound than a person in a boat that is also 1 000 m distant? (Ignore the time it takes the sound to reach the water surface.)&#10;A) 0.652&#10;B) 2.12&#10;C) 2.24&#10;D) 2.77&#10;E) 2.90

Accepted Answer

The answer of A boat sounds a fog horn on...

Question 62

A speaker is producing 30 W of sound. At which of the following frequencies would it sound the loudest?&#10;A) 50 Hz&#10;B) 100 Hz&#10;C) 500 Hz&#10;D) 1 000 Hz&#10;E) 10 000 Hz

Accepted Answer

The answer of A speaker is producing 30 W of...

Question 63

A source of sound waves is placed at the center of a very large sound-reflecting wall. The source emits 0.500 W of power. Two meters from the source the intensity in W/m² is A) 9.95 × 10−³. B) 1.99 × 10−². C) 0.313. D) 0.399. E) 0.625.

Accepted Answer

The answer of A source of sound waves is placed...

Question 64

When a workman strikes a steel pipeline with a hammer, he generates both longitudinal and transverse waves. The two types of reflected waves return 2.4 s apart. How far away is the reflection point? (For steel, v_L = 6.2 km/s, v_T = 3.2 km/s)

Accepted Answer

The answer of When a workman strikes a steel pipeline...

Deck 18: Superposition and Standing Waves