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Deck 14: Oscillations

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Question
In simple harmonic motion, the speed is greatest at that point in the cycle when

A)the magnitude of the acceleration is a maximum.
B)the displacement is a maximum.
C)the magnitude of the acceleration is a minimum.
D)the potential energy is a maximum.
E)the kinetic energy is a minimum.
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Question
Which of the following are characteristics of a mass in simple harmonic motion? I. The motion repeats at regular intervals.
II. The motion is sinusoidal.
III. The restoring force is proportional to the displacement from equilibrium.

A)I and II only
B)I and III only
C)II and III only
D)all of the above
E)none of the above
Question
A student designs a clock using a mass and a spring. Each oscillation of the mass advances the clock by one second. When the student builds the clock, he discovers he erred and each oscillation takes two seconds. What change can he make to fix the clock?

A)double the amplitude of the oscillations
B)quadruple the spring constant of the spring
C)double the spring constant of the spring
D)quadruple the mass
E)double the mass
Question
In designing buildings to be erected in an area prone to earthquakes, should you try to have a small or a large amount of damping?
Question
A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the mass is doubled to 2M?

A) <strong>A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the mass is doubled to 2M?</strong> A) T B)T C)T/2 D)2T E)4T <div style=padding-top: 35px> T
B)T
C)T/2
D)2T
E)4T
Question
Simple harmonic motion is always sinusoidal.
Question
Two players are enjoying a steady volley in a game of ping-pong, in which the motion of the ball is repeated regularly. Is the motion of the ball simple harmonic motion?
Question
The period and frequency of a simple pendulum depend on the mass of the pendulum bob.
Question
A mass is oscillating on a spring with an amplitude of 8.3 cm and a period of 4.6 s. Write an expression for its position, x, as a function of time, if x is equal to 8.3 cm at t = 0 s.
Question
Why are troops instructed to break step when they are marching over a bridge?
Question
Any oscillating system for which the net restoring force is directly proportional to the displacement is said to exhibit simple harmonic motion.
Question
The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46 The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46 )t]. Write an expression for the velocity of the particle as a function of time.<div style=padding-top: 35px> )t]. Write an expression for the velocity of the particle as a function of time.
Question
The projection of circular motion onto a straight line is simple harmonic motion.
Question
In designing buildings to be erected in an area prone to earthquakes, what relationship should the designer try to achieve between the natural frequencies of the building and the typical earthquake frequencies?
Question
A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the amplitude of the motion is increased to 2A?

A)2T
B)T/2
C) <strong>A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the amplitude of the motion is increased to 2A?</strong> A)2T B)T/2 C) T D)4T E)T <div style=padding-top: 35px> T
D)4T
E)T
Question
Increasing the damping constant beyond that required for critical damping makes the system approach equilibrium more quickly.
Question
The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46 s-1)t]. Write an expression for the acceleration of the particle as a function of time.
Question
In a grandfather clock, the pendulum measures the time elapsed. A grandfather clock is gaining time. Should you shorten or lengthen the pendulum?
Question
Should the tuner on a radio have small or large damping?
Question
In simple harmonic motion, the acceleration is proportional to

A)the velocity.
B)the frequency.
C)the amplitude.
D)the displacement.
E)all of the above
Question
Doubling only the spring constant of a vibrating mass-and-spring system produces what effect on the system's mechanical energy?

A)increases the energy by a factor of square root of two
B)increases the energy by a factor of two
C)increases the energy by a factor of three
D)increases he energy by a factor of four
E)produces no change
Question
Doubling only the amplitude of a vibrating mass-and-spring system produces what effect on the system's mechanical energy?

A)increases the energy by a factor of square root of two
B)increases the energy by a factor of two
C)increases the energy by a factor of three
D)increases the energy by a factor of four
E)produces no change
Question
A nail is stuck into the side of a car tire. As the car drives down a level road at constant speed, which of the following is simple harmonic motion?

A)the motion of the center of the tire
B)the vertical component of motion of the nail
C)the horizontal component of motion of the nail
D)both answers A and B
E)none of the above
Question
A mass on a spring undergoes SHM. When the mass passes through the equilibrium position, its instantaneous velocity

A)is maximum.
B)is less than maximum, but not zero.
C)is zero.
D)cannot be determined without mass information given.
E)cannot be determined without spring constant information given.
Question
What is impossible about the following situation? An object in simple harmonic motion has an equilibrium position x = 0.00 m. At some instant in time, the position of the object is +3.00 m, the velocity is -2.00 m/s, and the acceleration is +9.00 m/s2.

A)The numerical value of the velocity is smaller than the distance from the equilibrium position, but the numerical value of the magnitude of the acceleration is larger than the distance from equilibrium.
B)The velocity is opposite in direction to the displacement.
C)The acceleration is greater than the speed.
D)The speed is less than the displacement.
E)The displacement from equilibrium and the acceleration are in the same direction.
Question
The x-component of motion of an object is given by x(t) = Axcos(ωxt + φx) and the y-component of motion of the object is given by y(t) = Aycos(ωyt + φy). What relationships between the A,ω, and φ parameters must be true so that the motion of the object is on a circle?

A)Ax = Ay, ωx = ωy, and φx = φy
B)Ax = ±Ay, ωx = ±ωy
C)Ax = ±Ay, ωx = ωy, and φx = φy ± π/2
D)Ax = Ay, ωx = ±ωy, and φx = φy
E)Ax = ±Ay, ωx = ±ωy, and φx = φy ± π/2
Question
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its potential energy is a minimum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
Question
A mass on a spring undergoes SHM. When the mass is at maximum displacement from equilibrium, its instantaneous acceleration

A)is a maximum.
B)is less than maximum, but not zero.
C)is zero.
D)cannot be determined without mass information given.
E)cannot be determined without spring constant information given.
Question
Doubling only the mass of a vibrating mass-and-spring system produces what effect on the system's mechanical energy?

A)increases the energy by a factor of square root of two
B)increases the energy by a factor of two
C)increases the energy by a factor of three
D)increases the energy by a factor of four
E)produces no change
Question
The total mechanical energy of a simple harmonic oscillator is

A)zero as it passes the equilibrium point.
B)zero when it reaches the maximum displacement.
C)a maximum when it passes through the equilibrium point.
D)a minimum when it passes through the equilibrium point.
E)constant.
Question
If you take a given pendulum to the Moon, where the acceleration of gravity is less than on Earth, the resonant frequency of the pendulum will

A)increase.
B)decrease.
C)not change.
D)become zero.
E)either increase or decrease; it depends on its length to mass ratio.
Question
FIGURE 14-1 <strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E) <div style=padding-top: 35px>
Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s-1?

A)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E) <div style=padding-top: 35px>
B)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E) <div style=padding-top: 35px>
C)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E) <div style=padding-top: 35px>
D)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E) <div style=padding-top: 35px>
E)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E) <div style=padding-top: 35px>
Question
A vertical spring has a mass hanging from it, which is displaced from the equilibrium position and begins to oscillate. At what point does the system have the least potential energy?

A)at the highest point
B)at one-fourth of the distance between the highest point and lowest point
C)at the lowest point
D)at the point where the spring is unstretched
E)at the equilibrium point
Question
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its potential energy is a maximum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
Question
FIGURE 14-1 <strong>FIGURE 14-1 The simple harmonic motion of an object is shown in Fig. 14-1. What is the position of the object as a function of time?</strong> A)x(t) = (4.0 m)sin[(2π/8.0 s)t + π/3.0] B)x(t) = (4.0 m)cos[(2π/8.0 s)t + 2π/3.0] C)x(t) = (4.0 m)cos[(2π/8.0 s)t + π/3.0] D)x(t) = (4.0 m)cos[(2π/8.0 s)t - π/3.0] E)x(t) = (8.0 m)cos[(2π/8.0 s)t + π/3.0] <div style=padding-top: 35px>
The simple harmonic motion of an object is shown in Fig. 14-1. What is the position of the object as a function of time?

A)x(t) = (4.0 m)sin[(2π/8.0 s)t + π/3.0]
B)x(t) = (4.0 m)cos[(2π/8.0 s)t + 2π/3.0]
C)x(t) = (4.0 m)cos[(2π/8.0 s)t + π/3.0]
D)x(t) = (4.0 m)cos[(2π/8.0 s)t - π/3.0]
E)x(t) = (8.0 m)cos[(2π/8.0 s)t + π/3.0]
Question
A pendulum clock on the surface of the earth has a period of 1.00 s. On a distant planet, the length of the pendulum must be shortened slightly to have a period of 1.00 s. What is true about the acceleration of gravity on the distant planet?

A)The gravitational acceleration of the planet is 0.
B)The gravitational acceleration of the planet is slightly greater than g.
C)The gravitational acceleration of the planet is slightly less than g.
D)There is no gravitational acceleration on the planet.
E)The gravitational acceleration of the planet is equal to g.
Question
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its kinetic energy is a minimum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
Question
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its kinetic energy is a maximum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
Question
A mass on a spring undergoes SHM. When the mass is at its maximum displacement from equilibrium, its instantaneous velocity

A)is maximum.
B)is less than maximum, but not zero.
C)is zero.
D)cannot be determined without mass information given.
E)cannot be determined without spring constant information given.
Question
A simple pendulum consists of a mass M attached to a weightless string of length L. For this system, when undergoing small oscillations

A)the frequency is proportional to the amplitude.
B)the frequency is inversely proportional to the amplitude.
C)the period is proportional to the amplitude.
D)the frequency is independent of the mass M.
E)the frequency is independent of the length L.
Question
FIGURE 14-2 <strong>FIGURE 14-2 Curve C in Fig. 14-2 represents</strong> A)an underdamped situation. B)an overdamped situation. C)a moderately damped situation. D)critical damping. E)none of the above <div style=padding-top: 35px>
Curve C in Fig. 14-2 represents

A)an underdamped situation.
B)an overdamped situation.
C)a moderately damped situation.
D)critical damping.
E)none of the above
Question
FIGURE 14-2 <strong>FIGURE 14-2 Curve B in Fig. 14-2 represents</strong> A)an underdamped situation. B)an overdamped situation. C)a moderately damped situation. D)critical damping. E)none of the above <div style=padding-top: 35px>
Curve B in Fig. 14-2 represents

A)an underdamped situation.
B)an overdamped situation.
C)a moderately damped situation.
D)critical damping.
E)none of the above
Question
A mass of 0.150 kg is attached to a spring with a force constant of 3.58 N/m and undergoes simple harmonic oscillations. What is the period of the oscillations?

A)2.57 s
B)0.527 s
C)0.263 s
D)1.14 s
E)1.29 s
Question
A 1.5-kg mass attached to spring with a force constant of 20.0 N/m oscillates on a horizontal, frictionless track. At t= 0, the mass is released from rest at x= 10.0 cm. (That is, the spring is stretched by 10.00 cm.)(a) Determine the frequency of the oscillations.
(b) Determine the maximum speed of the mass. Where does the maximum speed occur?
(c) Determine the maximum acceleration of the mass. Where does the maximum acceleration occur?
(d) Determine the total energy of the oscillating system.
(e) Express the displacement as a function of time.
Question
FIGURE 14-2 <strong>FIGURE 14-2 Curve A in Fig. 14-2 represents</strong> A)an underdamped situation. B)an overdamped situation. C)a moderately damped situation. D)critical damping. E)none of the above <div style=padding-top: 35px>
Curve A in Fig. 14-2 represents

A)an underdamped situation.
B)an overdamped situation.
C)a moderately damped situation.
D)critical damping.
E)none of the above
Question
A mass is oscillating on a spring with a period of 4.60 s. At t = 0 s the mass has zero speed and is at x = 8.30 cm.
(a) What is the value of t the first time after t = 0 s that that the mass is at x = 4.15 cm?
(b) What is its acceleration at t = 2.50 s?
Question
Grandfather clocks are designed in a way that the weight at the bottom of the pendulum can be moved up or down by turning a small screw. Suppose you have a grandfather clock at home that runs fast. Should you turn the adjusting screw so as to raise the weight or lower the weight?

A)Raise it.
B)Lower it.
C)It doesn't matter if you raise or lower the weight, as long as you displace it by the right amount.
D)It doesn't matter if you raise or lower the weight, as long as you displace it with the correct initial velocity.
E)Raising or lowering the weight doesn't help, the screw is there so that you can add or take away weight.
Question
For a forced vibration, the amplitude of vibration is found to depend on the

A)sum of the external frequency and the natural frequency.
B)difference of the external frequency and the natural frequency.
C)product of the external frequency and the natural frequency.
D)ratio of the external frequency and the natural frequency.
E)ratio of the natural frequency and the external frequency.
Question
A sewing machine needle moves up and down in simple harmonic motion with an amplitude of 1.27 cm and a frequency of 2.55 Hz.
(a) What is the maximum speed of the needle?
(b) What is the maximum acceleration of the needle?
Question
A pendulum is made by suspending a solid circular disk from a pivot point that is at the edge of the disk with the plane of the disk lying in the vertical plane. The period of oscillation of the disk is T. If a disk with the same radius but a mass four times is great is suspended the same way, what will be its period of oscillation?

A)4T
B)T/2
C)2T
D)T
E)T/4
Question
For a damped driven harmonic oscillator, the frequency at which the amplitude is maximum is

A)greater than the natural frequency of oscillation.
B)equal to the natural frequency of oscillation.
C)at an infinite frequency.
D)zero.
E)less than the natural frequency of oscillation.
Question
When a mass of 180 g is attached to a vertical spring and lowered to its equilibrium position, it is found that the spring extends 12 cm. If the mass is now displaced from its equilibrium position, what is the period of the resulting oscillations?

A)2.2 s
B)3.7 s
C)0.69 s
D)9.0 s
E)1.5 s
Question
Increasing the amplitude of a mass-and-spring system causes what kind of change in the resonant frequency of the system? (Assume no other changes in the system.)

A)The frequency increases.
B)The frequency decreases.
C)There is no change in the frequency.
D)The frequency depends on the displacement, not the amplitude.
Question
Grandfather clocks are designed in a way that the weight at the bottom of the pendulum can be moved up or down by turning a small screw. Suppose you have a grandfather clock at home that runs slow. Should you turn the adjusting screw so as to raise the weight or lower the weight?

A)Raise it.
B)Lower it.
C)It doesn't matter if you raise or lower the weight as long as you displace it by the right amount.
D)It doesn't matter if you raise or lower the weight, as long as you displace it with the correct initial velocity.
E)Raising or lowering the weight doesn't help, the screw is there so that you can add or take away weight.
Question
A mass of 0.250 kg is attached to a spring and undergoes simple harmonic oscillations with a period of 0.640 s. What is the force constant of the spring?

A)2.45 N/m
B)12.1 N/m
C)24.1 N/m
D)0.102 N/m
E)0.610 N/m
Question
The design considerations for a timing mechanism require that a mass of 1.6 g should undergo 5 oscillations per second when it is attached to a spring. What should the force constant of a spring be to achieve this?

A)15.6 N/m
B)3.1 N/m
C)7.2 N/m
D)1.6 N/m
E)8.0 N/m
Question
The amplitude of a 3.00-kg object in simple harmonic motion is 10.0 m. The maximum speed of the object is 5.00 m/s What is the frequency of simple harmonic motion?

A)0.500 Hz
B)2.78 × 10-2 Hz
C)2.00 Hz
D)7.96 × 10-2 Hz
E)3.14 Hz
Question
A 0.50-kg mass is attached to a spring of spring constant 20 N/m along a horizontal, frictionless surface. The object oscillates in simple harmonic motion and has a speed of 1.5 m/s at the equilibrium position.
(a) What is the amplitude of vibration?
(b) At what location are the kinetic energy and the potential energy the same?
Question
Increasing the spring constant k of a mass-and-spring system causes what kind of change in the resonant frequency of the system? (Assume no change in the system's mass m.)

A)The frequency increases.
B)The frequency decreases.
C)There is no change in the frequency.
D)The frequency increases if the ratio k/m is greater than or equal to 1.
E)The frequency decreases if the ratio k/m is less than 1.
Question
Increasing the mass m of a mass-and-spring system causes what kind of change in the resonant frequency of the system? (Assume no change in the system's spring constant k.)

A)The frequency increases.
B)The frequency decreases.
C)There is no change in the frequency.
D)The frequency increases if the ratio k/m is greater than or equal to 1.
E)The frequency decreases if the ratio k/m is less than 1.
Question
The position of a mass that is oscillating on a spring is given by x = (12.3 cm) cos[(1.26s-1)t]. What is the velocity of the mass when t = 0.815 s?

A)- 13.3 cm/s
B)13.3 cm/s
C)8.02 cm/s
D)- 8.02 cm/s
E)0 cm/s
Question
The tip of the needle of a sewing machine executes simple harmonic motion with an amplitude of 1.2 cm and an angular frequency ω = 62 rad/s. What is the total distance traveled by the needle in 1.9 s?

A)27 cm
B)40 cm
C)1.1 cm
D)90 cm
E)140 cm
Question
The maximum displacement of a mass attached to a spring is 0.122 m, while its highest acceleration is 0.953 m/s2. What is its maximum speed?

A)0.358 m/s
B)0.108 m/s
C)0.831 m/s
D)0.341 m/s
E)0.538 m/s
Question
What is the total energy of a 300-g mass that is attached to a horizontal spring with a force constant of 260 N/m and oscillates along a frictionless horizontal surface with an amplitude of 8.0 cm?

A)21 J
B)0.83 J
C)2.4 J
D)1.6 J
E)6.2 J
Question
A mass of 1.53 kg is attached to a spring and the system is undergoing simple harmonic oscillations with a frequency of 1.95 Hz and an amplitude of 7.50 cm. What is the speed of the mass when it is 3.00 cm from its equilibrium position?

A)0.0368 m/s
B)0.551 m/s
C)0.421 m/s
D)0.842 m/s
E)0.919 m/s
Question
A mass of 0.150 kg is attached to a spring with a force constant of 3.58 N/m and undergoes simple harmonic oscillations with an amplitude of 7.50 cm. What is the total mechanical energy of the system?

A)0.0201 J
B)0.0101 J
C)0.269 J
D)0.134 J
E)0 J
Question
The position of a mass that is oscillating on a spring is given by x = (12.3 cm) cos[(1.26s-1)t]. What is the acceleration of the mass when t = 0.825 s?

A)9.89 cm/s2
B)-9.89 cm/s2
C)10.6 cm/s2
D)-10.6 cm/s2
E)0 cm/s2
Question
An air conditioning unit is vibrating in simple harmonic motion with a period of 0.27 s and a range (from the maximum in one direction to the maximum in the other) of 3.0 cm. At t = 0 it is at its central position and moving in the +x direction. What is its position when t = 55 s?

A)x = -0.430 cm
B)x = -0.511 cm
C)x = 0.511 cm
D)x = -1.41 cm
E)x = -1.44 cm
Question
A simple harmonic oscillator has an amplitude of 3.50 cm and a maximum speed of 28.0 cm/s. What is its speed when the displacement is 1.75 cm?

A)12.0 cm/s
B)24.2 cm/s
C)14.2 cm/s
D)15.0 cm/s
E)17.0 cm/s
Question
A mass of 1.53 kg is attached to a spring and the system is undergoing simple harmonic oscillations with a frequency of 1.95 Hz and an amplitude of 7.50 cm. What is the total mechanical energy of the system?

A)0.844 J
B)0.646 J
C)0.633 J
D)0.955 J
E)0 J
Question
The amplitude of a 3.00-kg object in simple harmonic motion is 6.00 m. The maximum acceleration of the object is 5.00 m/s2. What is the period of simple harmonic motion?

A)6.88 s
B)1.20 s
C)0.278 s
D)0.833 s
E)7.54 s
Question
The position of an air-track cart that is oscillating on a spring is given by x = (12.4 cm) cos[(6.35s-1)t]. At what value of t after t = 0 s is the cart first located at x = 8.47 cm?

A)4.34 s
B)0.108 s
C)0.129 s
D)7.39 s
E)7.75 s
Question
The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46s-1)t]. What is the period of this motion?

A)1.74 s
B)1.15 s
C)1.32 s
D)0.869 s
E)0.314 s
Question
The velocity of a mass attached to a spring is given by v = (1.5 cm/s) sin(ωt + π/2), where ω = 3.0 rad/s. What is the corresponding expression for x?

A)x = -(4.50 cm) sin(ωt + π/2)
B)x = (4.50 cm) cos(ωt + π/2)
C)x = -(0.50 cm) cos(ωt - π/2)
D)x = -(0.50 cm) cos(ωt + π/2)
E)x = -(0.50 cm) sin(ωt + π/2)
Question
A 30-g bullet traveling horizontally at 300 m/s strikes a 1.0-kg block which is attached to a horizontal spring with a force constant of 2000 N/m and rests on a frictionless horizontal surface. The spring is on the far side of the block and aligned with the direction of travel of the bullet. The bullet becomes embedded in the block and, as a result of the impact, and the block slides against the spring. How far is the spring compressed before it reverses its direction of travel?

A)0.20 m
B)0.58 m
C)1.2 m
D)0.40 m
E)0.039 m
Question
What is the maximum kinetic energy of a 2.00-kg mass moving with simple harmonic motion with an amplitude 5.00 cm and period 0.300 s?

A)1.10 J
B)0.444 J
C)0.222 J
D)0.174 J
E)0.0278 J
Question
The position of a mass that is oscillating on a spring is given by x = (18.3 cm) cos[(2.35s-1)t]. What is the frequency of this motion?

A)0.426 Hz
B)1.34 Hz
C)2.67 Hz
D)0.128 Hz
E)0.374 Hz
Question
A 4.20-g bullet embeds itself in a 20.0-kg block, which is attached to a horizontal spring with a force constant of 980 N/m. The maximum compression of the spring is 2.40 cm. What is the speed of the bullet just before it hits the block?

A)800 m/s
B)700 m/s
C)672 m/s
D)900 m/s
E)952 m/s
Question
The maximum speed of a 3.00-kg object in simple harmonic motion is 4.00 m/s. The maximum acceleration of the object is 5.00 m/s2. What is the period of simple harmonic motion?

A)1.25 s
B)0.417 s
C)0.800 s
D)5.03 s
E)3.75 s
Question
A 16.2-g bullet with an initial speed of 850 m/s embeds itself in a 40.0-kg block, which is attached to a horizontal spring with a force constant of 1000 N/m. What is the maximum compression of the spring?

A)6.34 cm
B)5.57 cm
C)3.42 cm
D)1.26 cm
E)6.88 cm
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Deck 14: Oscillations
1
In simple harmonic motion, the speed is greatest at that point in the cycle when

A)the magnitude of the acceleration is a maximum.
B)the displacement is a maximum.
C)the magnitude of the acceleration is a minimum.
D)the potential energy is a maximum.
E)the kinetic energy is a minimum.
the magnitude of the acceleration is a minimum.
2
Which of the following are characteristics of a mass in simple harmonic motion? I. The motion repeats at regular intervals.
II. The motion is sinusoidal.
III. The restoring force is proportional to the displacement from equilibrium.

A)I and II only
B)I and III only
C)II and III only
D)all of the above
E)none of the above
all of the above
3
A student designs a clock using a mass and a spring. Each oscillation of the mass advances the clock by one second. When the student builds the clock, he discovers he erred and each oscillation takes two seconds. What change can he make to fix the clock?

A)double the amplitude of the oscillations
B)quadruple the spring constant of the spring
C)double the spring constant of the spring
D)quadruple the mass
E)double the mass
quadruple the spring constant of the spring
4
In designing buildings to be erected in an area prone to earthquakes, should you try to have a small or a large amount of damping?
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5
A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the mass is doubled to 2M?

A) <strong>A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the mass is doubled to 2M?</strong> A) T B)T C)T/2 D)2T E)4T T
B)T
C)T/2
D)2T
E)4T
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6
Simple harmonic motion is always sinusoidal.
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7
Two players are enjoying a steady volley in a game of ping-pong, in which the motion of the ball is repeated regularly. Is the motion of the ball simple harmonic motion?
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8
The period and frequency of a simple pendulum depend on the mass of the pendulum bob.
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9
A mass is oscillating on a spring with an amplitude of 8.3 cm and a period of 4.6 s. Write an expression for its position, x, as a function of time, if x is equal to 8.3 cm at t = 0 s.
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10
Why are troops instructed to break step when they are marching over a bridge?
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11
Any oscillating system for which the net restoring force is directly proportional to the displacement is said to exhibit simple harmonic motion.
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12
The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46 The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46 )t]. Write an expression for the velocity of the particle as a function of time. )t]. Write an expression for the velocity of the particle as a function of time.
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13
The projection of circular motion onto a straight line is simple harmonic motion.
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14
In designing buildings to be erected in an area prone to earthquakes, what relationship should the designer try to achieve between the natural frequencies of the building and the typical earthquake frequencies?
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15
A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the amplitude of the motion is increased to 2A?

A)2T
B)T/2
C) <strong>A mass M is attached to a spring with spring constant k. When this system is set in motion with amplitude A, it has a period T. What is the period if the amplitude of the motion is increased to 2A?</strong> A)2T B)T/2 C) T D)4T E)T T
D)4T
E)T
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16
Increasing the damping constant beyond that required for critical damping makes the system approach equilibrium more quickly.
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17
The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46 s-1)t]. Write an expression for the acceleration of the particle as a function of time.
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18
In a grandfather clock, the pendulum measures the time elapsed. A grandfather clock is gaining time. Should you shorten or lengthen the pendulum?
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19
Should the tuner on a radio have small or large damping?
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20
In simple harmonic motion, the acceleration is proportional to

A)the velocity.
B)the frequency.
C)the amplitude.
D)the displacement.
E)all of the above
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21
Doubling only the spring constant of a vibrating mass-and-spring system produces what effect on the system's mechanical energy?

A)increases the energy by a factor of square root of two
B)increases the energy by a factor of two
C)increases the energy by a factor of three
D)increases he energy by a factor of four
E)produces no change
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22
Doubling only the amplitude of a vibrating mass-and-spring system produces what effect on the system's mechanical energy?

A)increases the energy by a factor of square root of two
B)increases the energy by a factor of two
C)increases the energy by a factor of three
D)increases the energy by a factor of four
E)produces no change
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23
A nail is stuck into the side of a car tire. As the car drives down a level road at constant speed, which of the following is simple harmonic motion?

A)the motion of the center of the tire
B)the vertical component of motion of the nail
C)the horizontal component of motion of the nail
D)both answers A and B
E)none of the above
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24
A mass on a spring undergoes SHM. When the mass passes through the equilibrium position, its instantaneous velocity

A)is maximum.
B)is less than maximum, but not zero.
C)is zero.
D)cannot be determined without mass information given.
E)cannot be determined without spring constant information given.
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25
What is impossible about the following situation? An object in simple harmonic motion has an equilibrium position x = 0.00 m. At some instant in time, the position of the object is +3.00 m, the velocity is -2.00 m/s, and the acceleration is +9.00 m/s2.

A)The numerical value of the velocity is smaller than the distance from the equilibrium position, but the numerical value of the magnitude of the acceleration is larger than the distance from equilibrium.
B)The velocity is opposite in direction to the displacement.
C)The acceleration is greater than the speed.
D)The speed is less than the displacement.
E)The displacement from equilibrium and the acceleration are in the same direction.
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26
The x-component of motion of an object is given by x(t) = Axcos(ωxt + φx) and the y-component of motion of the object is given by y(t) = Aycos(ωyt + φy). What relationships between the A,ω, and φ parameters must be true so that the motion of the object is on a circle?

A)Ax = Ay, ωx = ωy, and φx = φy
B)Ax = ±Ay, ωx = ±ωy
C)Ax = ±Ay, ωx = ωy, and φx = φy ± π/2
D)Ax = Ay, ωx = ±ωy, and φx = φy
E)Ax = ±Ay, ωx = ±ωy, and φx = φy ± π/2
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27
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its potential energy is a minimum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
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28
A mass on a spring undergoes SHM. When the mass is at maximum displacement from equilibrium, its instantaneous acceleration

A)is a maximum.
B)is less than maximum, but not zero.
C)is zero.
D)cannot be determined without mass information given.
E)cannot be determined without spring constant information given.
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29
Doubling only the mass of a vibrating mass-and-spring system produces what effect on the system's mechanical energy?

A)increases the energy by a factor of square root of two
B)increases the energy by a factor of two
C)increases the energy by a factor of three
D)increases the energy by a factor of four
E)produces no change
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30
The total mechanical energy of a simple harmonic oscillator is

A)zero as it passes the equilibrium point.
B)zero when it reaches the maximum displacement.
C)a maximum when it passes through the equilibrium point.
D)a minimum when it passes through the equilibrium point.
E)constant.
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31
If you take a given pendulum to the Moon, where the acceleration of gravity is less than on Earth, the resonant frequency of the pendulum will

A)increase.
B)decrease.
C)not change.
D)become zero.
E)either increase or decrease; it depends on its length to mass ratio.
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32
FIGURE 14-1 <strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E)
Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s-1?

A)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E)
B)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E)
C)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E)
D)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E)
E)
<strong>FIGURE 14-1 Which of following is a graph of simple periodic motion with amplitude 2.00 cm, angular frequency 2.00 s<sup>-</sup><sup>1</sup>?</strong> A) B) C) D) E)
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33
A vertical spring has a mass hanging from it, which is displaced from the equilibrium position and begins to oscillate. At what point does the system have the least potential energy?

A)at the highest point
B)at one-fourth of the distance between the highest point and lowest point
C)at the lowest point
D)at the point where the spring is unstretched
E)at the equilibrium point
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34
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its potential energy is a maximum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
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35
FIGURE 14-1 <strong>FIGURE 14-1 The simple harmonic motion of an object is shown in Fig. 14-1. What is the position of the object as a function of time?</strong> A)x(t) = (4.0 m)sin[(2π/8.0 s)t + π/3.0] B)x(t) = (4.0 m)cos[(2π/8.0 s)t + 2π/3.0] C)x(t) = (4.0 m)cos[(2π/8.0 s)t + π/3.0] D)x(t) = (4.0 m)cos[(2π/8.0 s)t - π/3.0] E)x(t) = (8.0 m)cos[(2π/8.0 s)t + π/3.0]
The simple harmonic motion of an object is shown in Fig. 14-1. What is the position of the object as a function of time?

A)x(t) = (4.0 m)sin[(2π/8.0 s)t + π/3.0]
B)x(t) = (4.0 m)cos[(2π/8.0 s)t + 2π/3.0]
C)x(t) = (4.0 m)cos[(2π/8.0 s)t + π/3.0]
D)x(t) = (4.0 m)cos[(2π/8.0 s)t - π/3.0]
E)x(t) = (8.0 m)cos[(2π/8.0 s)t + π/3.0]
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36
A pendulum clock on the surface of the earth has a period of 1.00 s. On a distant planet, the length of the pendulum must be shortened slightly to have a period of 1.00 s. What is true about the acceleration of gravity on the distant planet?

A)The gravitational acceleration of the planet is 0.
B)The gravitational acceleration of the planet is slightly greater than g.
C)The gravitational acceleration of the planet is slightly less than g.
D)There is no gravitational acceleration on the planet.
E)The gravitational acceleration of the planet is equal to g.
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37
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its kinetic energy is a minimum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
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38
A mass is attached to a vertical spring and bobs up and down between points A and B. Where is the mass located when its kinetic energy is a maximum?

A)at either A or B
B)midway between A and B
C)one-third of the way between A and B
D)one-fourth of the way between A and B
E)none of the above
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39
A mass on a spring undergoes SHM. When the mass is at its maximum displacement from equilibrium, its instantaneous velocity

A)is maximum.
B)is less than maximum, but not zero.
C)is zero.
D)cannot be determined without mass information given.
E)cannot be determined without spring constant information given.
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40
A simple pendulum consists of a mass M attached to a weightless string of length L. For this system, when undergoing small oscillations

A)the frequency is proportional to the amplitude.
B)the frequency is inversely proportional to the amplitude.
C)the period is proportional to the amplitude.
D)the frequency is independent of the mass M.
E)the frequency is independent of the length L.
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41
FIGURE 14-2 <strong>FIGURE 14-2 Curve C in Fig. 14-2 represents</strong> A)an underdamped situation. B)an overdamped situation. C)a moderately damped situation. D)critical damping. E)none of the above
Curve C in Fig. 14-2 represents

A)an underdamped situation.
B)an overdamped situation.
C)a moderately damped situation.
D)critical damping.
E)none of the above
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42
FIGURE 14-2 <strong>FIGURE 14-2 Curve B in Fig. 14-2 represents</strong> A)an underdamped situation. B)an overdamped situation. C)a moderately damped situation. D)critical damping. E)none of the above
Curve B in Fig. 14-2 represents

A)an underdamped situation.
B)an overdamped situation.
C)a moderately damped situation.
D)critical damping.
E)none of the above
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43
A mass of 0.150 kg is attached to a spring with a force constant of 3.58 N/m and undergoes simple harmonic oscillations. What is the period of the oscillations?

A)2.57 s
B)0.527 s
C)0.263 s
D)1.14 s
E)1.29 s
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44
A 1.5-kg mass attached to spring with a force constant of 20.0 N/m oscillates on a horizontal, frictionless track. At t= 0, the mass is released from rest at x= 10.0 cm. (That is, the spring is stretched by 10.00 cm.)(a) Determine the frequency of the oscillations.
(b) Determine the maximum speed of the mass. Where does the maximum speed occur?
(c) Determine the maximum acceleration of the mass. Where does the maximum acceleration occur?
(d) Determine the total energy of the oscillating system.
(e) Express the displacement as a function of time.
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45
FIGURE 14-2 <strong>FIGURE 14-2 Curve A in Fig. 14-2 represents</strong> A)an underdamped situation. B)an overdamped situation. C)a moderately damped situation. D)critical damping. E)none of the above
Curve A in Fig. 14-2 represents

A)an underdamped situation.
B)an overdamped situation.
C)a moderately damped situation.
D)critical damping.
E)none of the above
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46
A mass is oscillating on a spring with a period of 4.60 s. At t = 0 s the mass has zero speed and is at x = 8.30 cm.
(a) What is the value of t the first time after t = 0 s that that the mass is at x = 4.15 cm?
(b) What is its acceleration at t = 2.50 s?
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47
Grandfather clocks are designed in a way that the weight at the bottom of the pendulum can be moved up or down by turning a small screw. Suppose you have a grandfather clock at home that runs fast. Should you turn the adjusting screw so as to raise the weight or lower the weight?

A)Raise it.
B)Lower it.
C)It doesn't matter if you raise or lower the weight, as long as you displace it by the right amount.
D)It doesn't matter if you raise or lower the weight, as long as you displace it with the correct initial velocity.
E)Raising or lowering the weight doesn't help, the screw is there so that you can add or take away weight.
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48
For a forced vibration, the amplitude of vibration is found to depend on the

A)sum of the external frequency and the natural frequency.
B)difference of the external frequency and the natural frequency.
C)product of the external frequency and the natural frequency.
D)ratio of the external frequency and the natural frequency.
E)ratio of the natural frequency and the external frequency.
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49
A sewing machine needle moves up and down in simple harmonic motion with an amplitude of 1.27 cm and a frequency of 2.55 Hz.
(a) What is the maximum speed of the needle?
(b) What is the maximum acceleration of the needle?
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50
A pendulum is made by suspending a solid circular disk from a pivot point that is at the edge of the disk with the plane of the disk lying in the vertical plane. The period of oscillation of the disk is T. If a disk with the same radius but a mass four times is great is suspended the same way, what will be its period of oscillation?

A)4T
B)T/2
C)2T
D)T
E)T/4
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51
For a damped driven harmonic oscillator, the frequency at which the amplitude is maximum is

A)greater than the natural frequency of oscillation.
B)equal to the natural frequency of oscillation.
C)at an infinite frequency.
D)zero.
E)less than the natural frequency of oscillation.
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52
When a mass of 180 g is attached to a vertical spring and lowered to its equilibrium position, it is found that the spring extends 12 cm. If the mass is now displaced from its equilibrium position, what is the period of the resulting oscillations?

A)2.2 s
B)3.7 s
C)0.69 s
D)9.0 s
E)1.5 s
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53
Increasing the amplitude of a mass-and-spring system causes what kind of change in the resonant frequency of the system? (Assume no other changes in the system.)

A)The frequency increases.
B)The frequency decreases.
C)There is no change in the frequency.
D)The frequency depends on the displacement, not the amplitude.
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54
Grandfather clocks are designed in a way that the weight at the bottom of the pendulum can be moved up or down by turning a small screw. Suppose you have a grandfather clock at home that runs slow. Should you turn the adjusting screw so as to raise the weight or lower the weight?

A)Raise it.
B)Lower it.
C)It doesn't matter if you raise or lower the weight as long as you displace it by the right amount.
D)It doesn't matter if you raise or lower the weight, as long as you displace it with the correct initial velocity.
E)Raising or lowering the weight doesn't help, the screw is there so that you can add or take away weight.
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55
A mass of 0.250 kg is attached to a spring and undergoes simple harmonic oscillations with a period of 0.640 s. What is the force constant of the spring?

A)2.45 N/m
B)12.1 N/m
C)24.1 N/m
D)0.102 N/m
E)0.610 N/m
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56
The design considerations for a timing mechanism require that a mass of 1.6 g should undergo 5 oscillations per second when it is attached to a spring. What should the force constant of a spring be to achieve this?

A)15.6 N/m
B)3.1 N/m
C)7.2 N/m
D)1.6 N/m
E)8.0 N/m
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57
The amplitude of a 3.00-kg object in simple harmonic motion is 10.0 m. The maximum speed of the object is 5.00 m/s What is the frequency of simple harmonic motion?

A)0.500 Hz
B)2.78 × 10-2 Hz
C)2.00 Hz
D)7.96 × 10-2 Hz
E)3.14 Hz
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58
A 0.50-kg mass is attached to a spring of spring constant 20 N/m along a horizontal, frictionless surface. The object oscillates in simple harmonic motion and has a speed of 1.5 m/s at the equilibrium position.
(a) What is the amplitude of vibration?
(b) At what location are the kinetic energy and the potential energy the same?
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59
Increasing the spring constant k of a mass-and-spring system causes what kind of change in the resonant frequency of the system? (Assume no change in the system's mass m.)

A)The frequency increases.
B)The frequency decreases.
C)There is no change in the frequency.
D)The frequency increases if the ratio k/m is greater than or equal to 1.
E)The frequency decreases if the ratio k/m is less than 1.
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60
Increasing the mass m of a mass-and-spring system causes what kind of change in the resonant frequency of the system? (Assume no change in the system's spring constant k.)

A)The frequency increases.
B)The frequency decreases.
C)There is no change in the frequency.
D)The frequency increases if the ratio k/m is greater than or equal to 1.
E)The frequency decreases if the ratio k/m is less than 1.
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61
The position of a mass that is oscillating on a spring is given by x = (12.3 cm) cos[(1.26s-1)t]. What is the velocity of the mass when t = 0.815 s?

A)- 13.3 cm/s
B)13.3 cm/s
C)8.02 cm/s
D)- 8.02 cm/s
E)0 cm/s
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62
The tip of the needle of a sewing machine executes simple harmonic motion with an amplitude of 1.2 cm and an angular frequency ω = 62 rad/s. What is the total distance traveled by the needle in 1.9 s?

A)27 cm
B)40 cm
C)1.1 cm
D)90 cm
E)140 cm
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63
The maximum displacement of a mass attached to a spring is 0.122 m, while its highest acceleration is 0.953 m/s2. What is its maximum speed?

A)0.358 m/s
B)0.108 m/s
C)0.831 m/s
D)0.341 m/s
E)0.538 m/s
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64
What is the total energy of a 300-g mass that is attached to a horizontal spring with a force constant of 260 N/m and oscillates along a frictionless horizontal surface with an amplitude of 8.0 cm?

A)21 J
B)0.83 J
C)2.4 J
D)1.6 J
E)6.2 J
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65
A mass of 1.53 kg is attached to a spring and the system is undergoing simple harmonic oscillations with a frequency of 1.95 Hz and an amplitude of 7.50 cm. What is the speed of the mass when it is 3.00 cm from its equilibrium position?

A)0.0368 m/s
B)0.551 m/s
C)0.421 m/s
D)0.842 m/s
E)0.919 m/s
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66
A mass of 0.150 kg is attached to a spring with a force constant of 3.58 N/m and undergoes simple harmonic oscillations with an amplitude of 7.50 cm. What is the total mechanical energy of the system?

A)0.0201 J
B)0.0101 J
C)0.269 J
D)0.134 J
E)0 J
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67
The position of a mass that is oscillating on a spring is given by x = (12.3 cm) cos[(1.26s-1)t]. What is the acceleration of the mass when t = 0.825 s?

A)9.89 cm/s2
B)-9.89 cm/s2
C)10.6 cm/s2
D)-10.6 cm/s2
E)0 cm/s2
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68
An air conditioning unit is vibrating in simple harmonic motion with a period of 0.27 s and a range (from the maximum in one direction to the maximum in the other) of 3.0 cm. At t = 0 it is at its central position and moving in the +x direction. What is its position when t = 55 s?

A)x = -0.430 cm
B)x = -0.511 cm
C)x = 0.511 cm
D)x = -1.41 cm
E)x = -1.44 cm
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69
A simple harmonic oscillator has an amplitude of 3.50 cm and a maximum speed of 28.0 cm/s. What is its speed when the displacement is 1.75 cm?

A)12.0 cm/s
B)24.2 cm/s
C)14.2 cm/s
D)15.0 cm/s
E)17.0 cm/s
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70
A mass of 1.53 kg is attached to a spring and the system is undergoing simple harmonic oscillations with a frequency of 1.95 Hz and an amplitude of 7.50 cm. What is the total mechanical energy of the system?

A)0.844 J
B)0.646 J
C)0.633 J
D)0.955 J
E)0 J
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71
The amplitude of a 3.00-kg object in simple harmonic motion is 6.00 m. The maximum acceleration of the object is 5.00 m/s2. What is the period of simple harmonic motion?

A)6.88 s
B)1.20 s
C)0.278 s
D)0.833 s
E)7.54 s
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72
The position of an air-track cart that is oscillating on a spring is given by x = (12.4 cm) cos[(6.35s-1)t]. At what value of t after t = 0 s is the cart first located at x = 8.47 cm?

A)4.34 s
B)0.108 s
C)0.129 s
D)7.39 s
E)7.75 s
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73
The position of a mass that is oscillating on a spring is given by x = (17.4 cm) cos[(5.46s-1)t]. What is the period of this motion?

A)1.74 s
B)1.15 s
C)1.32 s
D)0.869 s
E)0.314 s
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74
The velocity of a mass attached to a spring is given by v = (1.5 cm/s) sin(ωt + π/2), where ω = 3.0 rad/s. What is the corresponding expression for x?

A)x = -(4.50 cm) sin(ωt + π/2)
B)x = (4.50 cm) cos(ωt + π/2)
C)x = -(0.50 cm) cos(ωt - π/2)
D)x = -(0.50 cm) cos(ωt + π/2)
E)x = -(0.50 cm) sin(ωt + π/2)
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75
A 30-g bullet traveling horizontally at 300 m/s strikes a 1.0-kg block which is attached to a horizontal spring with a force constant of 2000 N/m and rests on a frictionless horizontal surface. The spring is on the far side of the block and aligned with the direction of travel of the bullet. The bullet becomes embedded in the block and, as a result of the impact, and the block slides against the spring. How far is the spring compressed before it reverses its direction of travel?

A)0.20 m
B)0.58 m
C)1.2 m
D)0.40 m
E)0.039 m
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76
What is the maximum kinetic energy of a 2.00-kg mass moving with simple harmonic motion with an amplitude 5.00 cm and period 0.300 s?

A)1.10 J
B)0.444 J
C)0.222 J
D)0.174 J
E)0.0278 J
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77
The position of a mass that is oscillating on a spring is given by x = (18.3 cm) cos[(2.35s-1)t]. What is the frequency of this motion?

A)0.426 Hz
B)1.34 Hz
C)2.67 Hz
D)0.128 Hz
E)0.374 Hz
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78
A 4.20-g bullet embeds itself in a 20.0-kg block, which is attached to a horizontal spring with a force constant of 980 N/m. The maximum compression of the spring is 2.40 cm. What is the speed of the bullet just before it hits the block?

A)800 m/s
B)700 m/s
C)672 m/s
D)900 m/s
E)952 m/s
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79
The maximum speed of a 3.00-kg object in simple harmonic motion is 4.00 m/s. The maximum acceleration of the object is 5.00 m/s2. What is the period of simple harmonic motion?

A)1.25 s
B)0.417 s
C)0.800 s
D)5.03 s
E)3.75 s
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80
A 16.2-g bullet with an initial speed of 850 m/s embeds itself in a 40.0-kg block, which is attached to a horizontal spring with a force constant of 1000 N/m. What is the maximum compression of the spring?

A)6.34 cm
B)5.57 cm
C)3.42 cm
D)1.26 cm
E)6.88 cm
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