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Deck 15: Oscillatory Motion
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Question
Question
A weight of mass m is at rest at O when suspended from a spring,as shown.When it is pulled down and released,it oscillates between positions A and B.Which statement about the system consisting of the spring and the mass is correct? 
A)The gravitational potential energy of the system is greatest at A.
B)The elastic potential energy of the system is greatest at O.
C)The rate of change of momentum has its greatest magnitude at A and B.
D)The rate of change of gravitational potential energy is smallest at O.
E)The rate of change of gravitational potential energy has its greatest magnitude at A and B.
A)The gravitational potential energy of the system is greatest at A.
B)The elastic potential energy of the system is greatest at O.
C)The rate of change of momentum has its greatest magnitude at A and B.
D)The rate of change of gravitational potential energy is smallest at O.
E)The rate of change of gravitational potential energy has its greatest magnitude at A and B.
Question
A torsional pendulum consists of a solid disk (mass = 2.0 kg,radius = 1.0 m)suspended by a wire attached to a rigid support.The body oscillates about the support wire.If the torsion constant is 16 N⋅m/rad.What is the angular frequency (in rad/s)? 
A)2
B)4
C)6
D)8
E)7
A)2
B)4
C)6
D)8
E)7
Question
An object of mass m is attached to string of length L.When it is released from point A,the object oscillates between points A and B.Which statement about the system consisting of the pendulum and the Earth is correct? 
A)The gravitational potential energy of the system is greatest at A and B.
B)The kinetic energy of mass m is greatest at point O.
C)The greatest rate of change of momentum occurs at A and B.
D)All of the above are correct.
E)Only (a)and (b)above are correct.
A)The gravitational potential energy of the system is greatest at A and B.
B)The kinetic energy of mass m is greatest at point O.
C)The greatest rate of change of momentum occurs at A and B.
D)All of the above are correct.
E)Only (a)and (b)above are correct.
Question
In the figure below,a disk (radius R = 1.0 m,mass = 2.0 kg)is suspended from a pivot a distance d = 0.25 m above its center of mass.For a circular disk, 
)The angular frequency (in rad/s)for small oscillations is approximately
A)4.2
B)2.1
C)1.5
D)1.0
E)3.8
)The angular frequency (in rad/s)for small oscillations is approximately
A)4.2
B)2.1
C)1.5
D)1.0
E)3.8
Question
Two circus clowns (each having a mass of 50 kg)swing on two flying trapezes (negligible mass,length 25 m)shown in the figure.At the peak of the swing,one grabs the other,and the two swing back to one platform.The time for the forward and return motion is 
A)10 s
B)50 s
C)15 s
D)20 s
E)25 s
A)10 s
B)50 s
C)15 s
D)20 s
E)25 s
Question
In the figure below,a hoop (radius R = 1.0 m,mass = 2.0 kg)having four spokes of negligible mass is suspended from a pivot a distance d = .25 m above its center of mass.The angular frequency (in rad/s)for small oscillations is approximately 
A)4.0
B)2.5
C)1.5
D)1.0
E)0.5
A)4.0
B)2.5
C)1.5
D)1.0
E)0.5
Question
Question
Three pendulums with strings of the same length and bobs of the same mass are pulled out to angles θ1,θ2 and θ3 respectively and released.The approximation sin θ = θ holds for all three angles,with θ3 > θ2 > θ1.How do the angular frequencies of the three pendulums compare?
A)ω3 > ω2 > ω1
B)Need to know amplitudes to answer this question.
C)Need to know
to answer this question.
D)ω1 > ω2 > ω3
E)ω1 = ω2 = ω3
A)ω3 > ω2 > ω1
B)Need to know amplitudes to answer this question.
C)Need to know
to answer this question.D)ω1 > ω2 > ω3
E)ω1 = ω2 = ω3
Question
The mass in the figure below slides on a frictionless surface.When the mass is pulled out,spring 1 is stretched a distance x1 from its equilibrium position and spring 2 is stretched a distance x2.The spring constants are k1 and k2 respectively.The force pulling back on the mass is: 
A)−k2x1.
B)−k2x2.
C)−(k1x1 + k2x2).
D)
.
E)
.
A)−k2x1.
B)−k2x2.
C)−(k1x1 + k2x2).
D)
.E)
. Question
Question
The figure shows a uniform rod (length L = 1.0 m,mass = 2.0 kg)suspended from a pivot a distance d = 0.25 m above its center of mass.The angular frequency (in rad/s)for small oscillations is approximately 
A)1.0
B)2.5
C)1.5
D)4.1
E)3.5
A)1.0
B)2.5
C)1.5
D)4.1
E)3.5
Question
A mass m = 2.0 kg is attached to a spring having a force constant k = 290 N/m as in the figure.The mass is displaced from its equilibrium position and released.Its frequency of oscillation (in Hz)is approximately 
A)12
B)0.50
C)0.010
D)1.9
E)0.080
A)12
B)0.50
C)0.010
D)1.9
E)0.080
Question
The mass in the figure slides on a frictionless surface.If m = 2 kg,k1 = 800 N/m and k2 = 500 N/m,the frequency of oscillation (in Hz)is approximately 
A)6
B)2
C)4
D)8
E)10
A)6
B)2
C)4
D)8
E)10
Question
A uniform rod (mass m = 1.0 kg and length L = 2.0 m)pivoted at one end oscillates in a vertical plane as shown below.The period of oscillation (in s)is approximately 
A)4.0
B)1.6
C)3.2
D)2.3
E)2.0
A)4.0
B)1.6
C)3.2
D)2.3
E)2.0
Question
A horizontal plank (m = 2.0 kg,L = 1.0 m)is pivoted at one end.A spring (k = 1.0 × 103 N/m)is attached at the other end,as shown in the figure.Find the angular frequency (in rad/s)for small oscillations. 
A)39
B)44
C)55
D)66
E)25
A)39
B)44
C)55
D)66
E)25
Question
Question
Question
A hoop,a solid cylinder,and a solid sphere all have the same mass m and the same radius R.Each is mounted to oscillate about an axis a distance 0.5 R from the center.The axis is perpendicular to the circular plane of the hoop and the cylinder and to an equatorial plane of the sphere as shown below.Which is the correct ranking in order of increasing angular frequency ω? 
A)hoop,cylinder,sphere
B)cylinder,sphere,hoop
C)sphere,cylinder,hoop
D)hoop,sphere,cylinder
E)sphere,hoop,cylinder
A)hoop,cylinder,sphere
B)cylinder,sphere,hoop
C)sphere,cylinder,hoop
D)hoop,sphere,cylinder
E)sphere,hoop,cylinder
Question
Question
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.The point at which the object has negative velocity and zero acceleration is
A)A
B)B
C)C
D)D
E)E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.The point at which the object has negative velocity and zero acceleration is
A)A
B)B
C)C
D)D
E)E
Question
Question
Question
Question
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.A point or points at which the object has positive velocity and zero acceleration is(are)
A)B
B)C
C)D
D)B and D
E)A and E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.A point or points at which the object has positive velocity and zero acceleration is(are)
A)B
B)C
C)D
D)B and D
E)A and E
Question
Question
Question
Question
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.The point at which the object has zero velocity and negative acceleration is
A)A
B)B
C)C
D)D
E)E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.The point at which the object has zero velocity and negative acceleration is
A)A
B)B
C)C
D)D
E)E
Question
Question
At sea level,at a latitude where 
,a pendulum that takes 2.00 s for a complete swing back and forth has a length of 0.993 m.What is the value of g in m/s2 at a location where the length of such a pendulum is 0.970 m?
A)0.098 3
B)3.05
C)9.57
D)10.0
E)38.3
,a pendulum that takes 2.00 s for a complete swing back and forth has a length of 0.993 m.What is the value of g in m/s2 at a location where the length of such a pendulum is 0.970 m?
A)0.098 3
B)3.05
C)9.57
D)10.0
E)38.3
Question
Question
Question
To double the total energy of a mass oscillating at the end of a spring with amplitude A,we need to
A)increase the angular frequency by
.
B)increase the amplitude by
.
C)increase the amplitude by 2.
D)increase the angular frequency by 2.
E)increase the amplitude by 4 and decrease the angular frequency by
.
A)increase the angular frequency by
.B)increase the amplitude by
.C)increase the amplitude by 2.
D)increase the angular frequency by 2.
E)increase the amplitude by 4 and decrease the angular frequency by
. Question
Question
Which of the following combinations of variables results in the greatest period for a pendulum?
A)length = L,mass = M,and maximum angular displacement = 3 degrees
B)length = 2L,mass = M/2,and maximum angular displacement = 1 degree
C)length = 1.5L,mass = 2M,and maximum angular displacement = 2 degrees
D)length =
L,mass = 
M,and maximum angular displacement = 
degrees
E)length =
L,mass = 4M,and maximum angular displacement = 4 degrees
A)length = L,mass = M,and maximum angular displacement = 3 degrees
B)length = 2L,mass = M/2,and maximum angular displacement = 1 degree
C)length = 1.5L,mass = 2M,and maximum angular displacement = 2 degrees
D)length =
L,mass = M,and maximum angular displacement = degreesE)length =
L,mass = 4M,and maximum angular displacement = 4 degrees Question
The oscillation of the 2.0-kg mass on a spring is described by 
Where x is in centimeters and t is in seconds.What is the force constant of the spring?
A)4.0 N/m
B)0.80 N/m
C)16 N/m
D)32 N/m
E)2.0
N/m
Where x is in centimeters and t is in seconds.What is the force constant of the spring?
A)4.0 N/m
B)0.80 N/m
C)16 N/m
D)32 N/m
E)2.0
N/m Question
Question
Question
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.The point at which the object has zero velocity and positive acceleration is
A)A
B)B
C)C
D)D
E)E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.The point at which the object has zero velocity and positive acceleration is
A)A
B)B
C)C
D)D
E)E
Question
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Deck 15: Oscillatory Motion
1
The motion of a particle connected to a spring is described by x = 10 sin (πt).At what time (in s)is the potential energy equal to the kinetic energy?
A)0
B)0.25
C)0.50
D)0.79
E)1.0
A)0
B)0.25
C)0.50
D)0.79
E)1.0
0.25
2
A weight of mass m is at rest at O when suspended from a spring,as shown.When it is pulled down and released,it oscillates between positions A and B.Which statement about the system consisting of the spring and the mass is correct?
A)The gravitational potential energy of the system is greatest at A.
B)The elastic potential energy of the system is greatest at O.
C)The rate of change of momentum has its greatest magnitude at A and B.
D)The rate of change of gravitational potential energy is smallest at O.
E)The rate of change of gravitational potential energy has its greatest magnitude at A and B.
A)The gravitational potential energy of the system is greatest at A.
B)The elastic potential energy of the system is greatest at O.
C)The rate of change of momentum has its greatest magnitude at A and B.
D)The rate of change of gravitational potential energy is smallest at O.
E)The rate of change of gravitational potential energy has its greatest magnitude at A and B.
The rate of change of momentum has its greatest magnitude at A and B.
3
A torsional pendulum consists of a solid disk (mass = 2.0 kg,radius = 1.0 m)suspended by a wire attached to a rigid support.The body oscillates about the support wire.If the torsion constant is 16 N⋅m/rad.What is the angular frequency (in rad/s)?
A)2
B)4
C)6
D)8
E)7
A)2
B)4
C)6
D)8
E)7
4
4
An object of mass m is attached to string of length L.When it is released from point A,the object oscillates between points A and B.Which statement about the system consisting of the pendulum and the Earth is correct?
A)The gravitational potential energy of the system is greatest at A and B.
B)The kinetic energy of mass m is greatest at point O.
C)The greatest rate of change of momentum occurs at A and B.
D)All of the above are correct.
E)Only (a)and (b)above are correct.
A)The gravitational potential energy of the system is greatest at A and B.
B)The kinetic energy of mass m is greatest at point O.
C)The greatest rate of change of momentum occurs at A and B.
D)All of the above are correct.
E)Only (a)and (b)above are correct.
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5
In the figure below,a disk (radius R = 1.0 m,mass = 2.0 kg)is suspended from a pivot a distance d = 0.25 m above its center of mass.For a circular disk,
)The angular frequency (in rad/s)for small oscillations is approximately
A)4.2
B)2.1
C)1.5
D)1.0
E)3.8
)The angular frequency (in rad/s)for small oscillations is approximately
A)4.2
B)2.1
C)1.5
D)1.0
E)3.8
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6
Two circus clowns (each having a mass of 50 kg)swing on two flying trapezes (negligible mass,length 25 m)shown in the figure.At the peak of the swing,one grabs the other,and the two swing back to one platform.The time for the forward and return motion is
A)10 s
B)50 s
C)15 s
D)20 s
E)25 s
A)10 s
B)50 s
C)15 s
D)20 s
E)25 s
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7
In the figure below,a hoop (radius R = 1.0 m,mass = 2.0 kg)having four spokes of negligible mass is suspended from a pivot a distance d = .25 m above its center of mass.The angular frequency (in rad/s)for small oscillations is approximately
A)4.0
B)2.5
C)1.5
D)1.0
E)0.5
A)4.0
B)2.5
C)1.5
D)1.0
E)0.5
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8
A body of mass 5.0 kg is suspended by a spring which stretches 10 cm when the mass is attached.It is then displaced downward an additional 5.0 cm and released.Its position as a function of time is approximately
A)y = −0.10 sin 9.9t
B)y = 0.10 cos 9.9t
C)y = −0.10 cos (9.9t + .1)
D)y = 0.10 sin (9.9t + 5)
E)y = −0.05 cos 9.9t
A)y = −0.10 sin 9.9t
B)y = 0.10 cos 9.9t
C)y = −0.10 cos (9.9t + .1)
D)y = 0.10 sin (9.9t + 5)
E)y = −0.05 cos 9.9t
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9
Three pendulums with strings of the same length and bobs of the same mass are pulled out to angles θ1,θ2 and θ3 respectively and released.The approximation sin θ = θ holds for all three angles,with θ3 > θ2 > θ1.How do the angular frequencies of the three pendulums compare?
A)ω3 > ω2 > ω1
B)Need to know amplitudes to answer this question.
C)Need to know to answer this question.
D)ω1 > ω2 > ω3
E)ω1 = ω2 = ω3
A)ω3 > ω2 > ω1
B)Need to know amplitudes to answer this question.
C)Need to know
to answer this question.D)ω1 > ω2 > ω3
E)ω1 = ω2 = ω3
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10
The mass in the figure below slides on a frictionless surface.When the mass is pulled out,spring 1 is stretched a distance x1 from its equilibrium position and spring 2 is stretched a distance x2.The spring constants are k1 and k2 respectively.The force pulling back on the mass is:
A)−k2x1.
B)−k2x2.
C)−(k1x1 + k2x2).
D) .
E) .
A)−k2x1.
B)−k2x2.
C)−(k1x1 + k2x2).
D)
.E)
. Unlock Deck
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11
A body oscillates with simple harmonic motion along the x axis.Its displacement varies with time according to the equation x = 5.0 cos (πt).The magnitude of the acceleration (in m/s2)of the body at t = 1.0 s is approximately
A)3.5
B)49
C)14
D)43
E)4.3
A)3.5
B)49
C)14
D)43
E)4.3
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12
The figure shows a uniform rod (length L = 1.0 m,mass = 2.0 kg)suspended from a pivot a distance d = 0.25 m above its center of mass.The angular frequency (in rad/s)for small oscillations is approximately
A)1.0
B)2.5
C)1.5
D)4.1
E)3.5
A)1.0
B)2.5
C)1.5
D)4.1
E)3.5
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13
A mass m = 2.0 kg is attached to a spring having a force constant k = 290 N/m as in the figure.The mass is displaced from its equilibrium position and released.Its frequency of oscillation (in Hz)is approximately
A)12
B)0.50
C)0.010
D)1.9
E)0.080
A)12
B)0.50
C)0.010
D)1.9
E)0.080
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14
The mass in the figure slides on a frictionless surface.If m = 2 kg,k1 = 800 N/m and k2 = 500 N/m,the frequency of oscillation (in Hz)is approximately
A)6
B)2
C)4
D)8
E)10
A)6
B)2
C)4
D)8
E)10
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15
A uniform rod (mass m = 1.0 kg and length L = 2.0 m)pivoted at one end oscillates in a vertical plane as shown below.The period of oscillation (in s)is approximately
A)4.0
B)1.6
C)3.2
D)2.3
E)2.0
A)4.0
B)1.6
C)3.2
D)2.3
E)2.0
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16
A horizontal plank (m = 2.0 kg,L = 1.0 m)is pivoted at one end.A spring (k = 1.0 × 103 N/m)is attached at the other end,as shown in the figure.Find the angular frequency (in rad/s)for small oscillations.
A)39
B)44
C)55
D)66
E)25
A)39
B)44
C)55
D)66
E)25
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17
A body oscillates with simple harmonic motion along the x axis.Its displacement varies with time according to the equation x = 5.0 sin (πt + π/3).The velocity (in m/s)of the body at t = 1.0 s is
A)+7.9
B)−7.9
C)−14
D)+14
E)−5.0
A)+7.9
B)−7.9
C)−14
D)+14
E)−5.0
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18
The amplitude of a system moving with simple harmonic motion is doubled.The total energy will then be
A)4 times as large
B)3 times as large
C)2 times as large
D)the same as it was
E)half as much
A)4 times as large
B)3 times as large
C)2 times as large
D)the same as it was
E)half as much
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19
A hoop,a solid cylinder,and a solid sphere all have the same mass m and the same radius R.Each is mounted to oscillate about an axis a distance 0.5 R from the center.The axis is perpendicular to the circular plane of the hoop and the cylinder and to an equatorial plane of the sphere as shown below.Which is the correct ranking in order of increasing angular frequency ω?
A)hoop,cylinder,sphere
B)cylinder,sphere,hoop
C)sphere,cylinder,hoop
D)hoop,sphere,cylinder
E)sphere,hoop,cylinder
A)hoop,cylinder,sphere
B)cylinder,sphere,hoop
C)sphere,cylinder,hoop
D)hoop,sphere,cylinder
E)sphere,hoop,cylinder
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20
A body oscillates with simple harmonic motion along the x axis.Its displacement varies with time according to the equation x = 5 sin (πt + π/3).The phase (in rad)of the motion at t = 2 s is
A)7π/3
B)π/3
C)π
D)5π/3
E)2π
A)7π/3
B)π/3
C)π
D)5π/3
E)2π
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21
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.The point at which the object has negative velocity and zero acceleration is
A)A
B)B
C)C
D)D
E)E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.The point at which the object has negative velocity and zero acceleration is
A)A
B)B
C)C
D)D
E)E
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22
A 2.00 m-long 6.00 kg ladder pivoted at the top hangs down from a platform at the circus.A 42.0 kg trapeze artist climbs to a point where her center of mass is at the center of the ladder and swings at the system's natural frequency.The angular frequency (in s−1)of the system of ladder and woman is
A)1.01.
B)3.07.
C)4.03.
D)8.05.
E)16.2.
A)1.01.
B)3.07.
C)4.03.
D)8.05.
E)16.2.
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23
An automobile (m = 1.00 × 103 kg)is driven into a brick wall in a safety test.The bumper behaves like a spring (k = 5.00 × 106 N/m),and is observed to compress a distance of 3.16 cm as the car is brought to rest.What was the initial speed of the automobile?
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24
An ore car of mass 4 000 kg starts from rest and rolls downhill on tracks from a mine.A spring with k = 400 000 N/m is located at the end of the tracks.At the spring's maximum compression,the car is at an elevation 10 m lower than its elevation at the starting point.How much is the spring compressed in stopping the ore car? Ignore friction.
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25
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.A point or points at which the object has positive velocity and zero acceleration is(are)
A)B
B)C
C)D
D)B and D
E)A and E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.A point or points at which the object has positive velocity and zero acceleration is(are)
A)B
B)C
C)D
D)B and D
E)A and E
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26
The mat of a trampoline is held by 32 springs,each having a spring constant of 5 000 N/m.A person with a mass of 40.0 kg jumps from a platform 1.93 m high onto the trampoline.Determine the stretch of each of the springs.
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27
Simple harmonic oscillations can be modeled by the projection of circular motion at constant angular velocity onto a diameter of the circle.When this is done,the analog along the diameter of the acceleration of the particle executing simple harmonic motion is
A)the displacement from the center of the diameter of the projection of the position of the particle on the circle.
B)the projection along the diameter of the velocity of the particle on the circle.
C)the projection along the diameter of tangential acceleration of the particle on the circle.
D)the projection along the diameter of centripetal acceleration of the particle on the circle.
E)meaningful only when the particle moving in the circle also has a non-zero tangential acceleration.
A)the displacement from the center of the diameter of the projection of the position of the particle on the circle.
B)the projection along the diameter of the velocity of the particle on the circle.
C)the projection along the diameter of tangential acceleration of the particle on the circle.
D)the projection along the diameter of centripetal acceleration of the particle on the circle.
E)meaningful only when the particle moving in the circle also has a non-zero tangential acceleration.
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28
A damped oscillator is released from rest with an initial displacement of 10.00 cm.At the end of the first complete oscillation the displacement reaches 9.05 cm.When 4 more oscillations are completed,what is the displacement reached?
A)7.41 cm
B)6.71 cm
C)6.07 cm
D)5.49 cm
E)5.25 cm
A)7.41 cm
B)6.71 cm
C)6.07 cm
D)5.49 cm
E)5.25 cm
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29
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.The point at which the object has zero velocity and negative acceleration is
A)A
B)B
C)C
D)D
E)E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.The point at which the object has zero velocity and negative acceleration is
A)A
B)B
C)C
D)D
E)E
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30
An archer pulls her bow string back 0.40 m by exerting a force that increases uniformly from zero to 240 N.What is the equivalent spring constant of the bow,and how much work is done in pulling the bow?
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31
At sea level,at a latitude where
,a pendulum that takes 2.00 s for a complete swing back and forth has a length of 0.993 m.What is the value of g in m/s2 at a location where the length of such a pendulum is 0.970 m?
A)0.098 3
B)3.05
C)9.57
D)10.0
E)38.3
,a pendulum that takes 2.00 s for a complete swing back and forth has a length of 0.993 m.What is the value of g in m/s2 at a location where the length of such a pendulum is 0.970 m?
A)0.098 3
B)3.05
C)9.57
D)10.0
E)38.3
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32
When a damping force is applied to a simple harmonic oscillator which has angular frequency ω0 in the absence of damping,the new angular frequency ω is such that
A)ω < ω0.
B)ω = ω0.
C)ω > ω0.
D)ωT < ω0T0.
E)ωT > ω0T0.
A)ω < ω0.
B)ω = ω0.
C)ω > ω0.
D)ωT < ω0T0.
E)ωT > ω0T0.
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33
In an inertia balance,a body supported against gravity executes simple harmonic oscillations in a horizontal plane under the action of a set of springs.If a 1.00 kg body vibrates at 1.00 Hz,a 2.00 kg body will vibrate at
A)0.500 Hz.
B)0.707 Hz.
C)1.00 Hz.
D)1.41 Hz.
E)2.00 Hz.
A)0.500 Hz.
B)0.707 Hz.
C)1.00 Hz.
D)1.41 Hz.
E)2.00 Hz.
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34
To double the total energy of a mass oscillating at the end of a spring with amplitude A,we need to
A)increase the angular frequency by .
B)increase the amplitude by .
C)increase the amplitude by 2.
D)increase the angular frequency by 2.
E)increase the amplitude by 4 and decrease the angular frequency by .
A)increase the angular frequency by
.B)increase the amplitude by
.C)increase the amplitude by 2.
D)increase the angular frequency by 2.
E)increase the amplitude by 4 and decrease the angular frequency by
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35
John says that the value of the function cos[ω(t + T)+ ϕ],obtained one period T after time t,is greater than cos(ωt + ϕ)by 2π.Larry says that it is greater by the addition of 1.00 to cos(ωt + ϕ).Which one,if either,is correct?
A)John,because ωT = 2π.
B)John,because ωT = 1 radian.
C)Larry,because ωT = 2π.
D)Larry,because ωT = 1 radian.
E)Neither,because cos(θ + 2π)= cosθ.
A)John,because ωT = 2π.
B)John,because ωT = 1 radian.
C)Larry,because ωT = 2π.
D)Larry,because ωT = 1 radian.
E)Neither,because cos(θ + 2π)= cosθ.
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36
Which of the following combinations of variables results in the greatest period for a pendulum?
A)length = L,mass = M,and maximum angular displacement = 3 degrees
B)length = 2L,mass = M/2,and maximum angular displacement = 1 degree
C)length = 1.5L,mass = 2M,and maximum angular displacement = 2 degrees
D)length = L,mass = M,and maximum angular displacement = degrees
E)length = L,mass = 4M,and maximum angular displacement = 4 degrees
A)length = L,mass = M,and maximum angular displacement = 3 degrees
B)length = 2L,mass = M/2,and maximum angular displacement = 1 degree
C)length = 1.5L,mass = 2M,and maximum angular displacement = 2 degrees
D)length =
L,mass = M,and maximum angular displacement = degreesE)length =
L,mass = 4M,and maximum angular displacement = 4 degrees Unlock Deck
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37
The oscillation of the 2.0-kg mass on a spring is described by
Where x is in centimeters and t is in seconds.What is the force constant of the spring?
A)4.0 N/m
B)0.80 N/m
C)16 N/m
D)32 N/m
E)2.0 N/m
Where x is in centimeters and t is in seconds.What is the force constant of the spring?
A)4.0 N/m
B)0.80 N/m
C)16 N/m
D)32 N/m
E)2.0
N/m Unlock Deck
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38
When a damping force is applied to a simple harmonic oscillator which has period T0 in the absence of damping,the new period T is such that
A)T < T0.
B)T = T0.
C)T > T0.
D)ωT < ω0T0.
E)ωT > ω0T0.
A)T < T0.
B)T = T0.
C)T > T0.
D)ωT < ω0T0.
E)ωT > ω0T0.
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39
Ellen says that whenever the acceleration is directly proportional to the displacement of an object from its equilibrium position,the motion of the object is simple harmonic motion.Mary says this is true only if the acceleration is opposite in direction to the displacement.Which one,if either,is correct?
A)Ellen,because ω2 is directly proportional to the constant multiplying the displacement and to the mass.
B)Ellen,because ω2 is directly proportional to the mass.
C)Mary,because ω2 is directly proportional to the constant multiplying the displacement and to the mass.
D)Mary,because ω2 is directly proportional to the mass.
E)Mary,because the second derivative of an oscillatory function like sin(ωt)or cos(ωt)is always proportional to the negative of the original function.
A)Ellen,because ω2 is directly proportional to the constant multiplying the displacement and to the mass.
B)Ellen,because ω2 is directly proportional to the mass.
C)Mary,because ω2 is directly proportional to the constant multiplying the displacement and to the mass.
D)Mary,because ω2 is directly proportional to the mass.
E)Mary,because the second derivative of an oscillatory function like sin(ωt)or cos(ωt)is always proportional to the negative of the original function.
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40
Exhibit 15-1
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are) Use this exhibit to answer the following question(s).
Refer to Exhibit 15-1.The point at which the object has zero velocity and positive acceleration is
A)A
B)B
C)C
D)D
E)E
A graph of position versus time for an object oscillating at the free end of a horizontal spring is shown below.A point or points at which the object has positive velocity and zero acceleration is(are)
Use this exhibit to answer the following question(s).Refer to Exhibit 15-1.The point at which the object has zero velocity and positive acceleration is
A)A
B)B
C)C
D)D
E)E
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41
The motion of a piston in an auto engine is simple harmonic.If the piston travels back and forth over a distance of 10 cm,and the piston has a mass of 1.5 kg,what is the maximum speed of the piston and the maximum force acting on the piston when the engine is running at 4 200 rpm?
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