Unit 6 Practice Test: Sound

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Unit 6 Practice Test: Sound Name: Multiple Guess Identify the letter of the choice that best completes the statement or answers the question. 1. A mass attached to a spring vibrates back and forth. At the equilibrium position, the a. the acceleration reaches a maximum. c. net force reaches a maximum. b. velocity reaches a maximum. d. velocity reaches zero. 2. A mass attached to a spring vibrates back and forth. At maximum displacement, the spring force and the a. velocity reach a maximum. c. acceleration reach a maximum. b. velocity reach zero. d. acceleration reach zero. 3. A simple pendulum swings in simple harmonic motion. At maximum displacement, a. the acceleration reaches a maximum. c. the acceleration reaches zero. b. the velocity reaches a maximum. d. the restoring forces reach zero. 4. If a force of 50 N stretches a spring 0.10 m, what is the spring constant? a. 5 N/m c. 5 N/m b. 500 N/m d. 500 N/m 5. A 0.20 kg mass suspended from a spring moves with simple harmonic motion. At the instant the mass is displaced from equilibrium by 0.05 m, what is its acceleration? (The spring constant is 10.0 N/m.) a. 1200 m/s 2 c. 0.10 m/s 2 b. 41 m/s 2 d. 2.5 m/s 2 6. A mass on a spring that has been compressed 0.1 m has a restoring force of 20 N. What is the spring constant? a. 10 N/m c. 200 N/m b. 20 N/m d. 300 N/m 7. The angle between the string of a pendulum at its equilibrium position and at its maximum displacement is its a. period. c. vibration. b. frequency. d. amplitude. 8. A pendulum swings through a total of 28. If the displacement is equal on each side of the equilibrium position, what is the amplitude of this vibration? (Disregard frictional forces acting on the pendulum.) a. 28 c. 56 b. 14 d. 7.0 9. Which of the following is the time it takes to complete a cycle of motion? a. amplitude c. frequency b. period d. revolution 10. Which of the following is the number of cycles or vibrations per unit of time? a. amplitude c. frequency b. period d. revolution 11. How are frequency and period related in simple harmonic motion? a. They are directly related. b. They are inversely related. c. They both measure the time per cycle. d. They both measure the number of cycles per unit of time. 12. An amusement park ride has a frequency of 0.05 Hz. What is the ride s period? a. 5 s c. 20 s b. 10 s d. 40 s 13. An amusement park ride swings back and forth once every 40.0 s. What is the ride s frequency? a. 2.50 10 2 Hz c. 25.0 10 2 Hz b. 5.00 10 2 Hz d. 40.0 10 2 Hz 14. By what factor should the length of a simple pendulum be changed if the period of vibration were to be tripled? a. 3 c. 9 b. 6 d. 27

15. A mass on a spring vibrates in simple harmonic motion at an amplitude of 8.0 cm. If the mass of the object is 0.20 kg and the spring constant is 130 N/m, what is the frequency? a. 1.5 Hz c. 4.0 Hz b. 8.7 Hz d. 1.6 Hz 16. What is the period of a 4.12 m long pendulum? a. 2.01 s c. 4.07 s b. 3.11 s d. 9.69 s 17. Which of the following is a single nonperiodic disturbance? a. pulse wave c. sine wave b. periodic wave d. transverse wave 18. Which of the following is a wave whose source is some form of repeating motion? a. pulse wave c. sine wave b. periodic wave d. transverse wave 19. One end of a taut rope is fixed to a post. What type of wave is demonstrated if the free end is quickly raised and lowered? a. pulse wave c. sine wave b. periodic wave d. transverse wave 20. In the waveform of the longitudinal wave shown above, the compressed regions correspond to a. the wavelength. c. troughs. b. crests. d. the mass. 21. In the waveform of the longitudinal wave shown above, the stretched regions correspond to a. the wavelength. c. troughs. b. crests. d. the mass. 22. A periodic wave has a wavelength of 0.50 m and a speed of 20 m/s. What is the wave frequency? a. 0.02 Hz c. 40 Hz b. 20 Hz d. 10 Hz 23. A musical tone sounded on a piano has a frequency of 410 Hz and a wavelength of 0.80 m. What is the speed of the sound wave? a. 170 m/s c. 330 m/s b. 240 m/s d. 590 m/s 24. A radio wave has a speed of 3.00 10 8 m/s and a frequency of 107 MHz. What is the wavelength? a. 3.21 m c. 0.100 m b. 45.0 m d. 2.79 m 25. Two waves can occupy the same space at the same time because waves a. are matter. c. do not cause interference patterns. b. are displacements of matter. d. cannot pass through one another. 26. What is the phase difference between two waves that are traveling in the same medium when they undergo constructive interference? a. 270 c. 90 b. 180 d. 0

27. Which of the following is the interference that results when individual displacements on the same side of the equilibrium position are added together to form the resultant wave? a. constructive c. complete constructive b. destructive d. complete destructive 28. Which of the following is the interference that results when individual displacements on opposite sides of the equilibrium position are added together to form the resultant wave? a. constructive c. complete constructive b. destructive d. complete destructive 29. Which of the following types of interference will occur in the figure above? a. partial constructive c. complete constructive b. partial destructive d. complete destructive 30. Which of the following types of interference will occur in the figure above? a. partial constructive c. complete constructive b. partial destructive d. complete destructive 31. At a fixed boundary, waves are a. neither reflected nor inverted. c. reflected and inverted. b. reflected but not inverted. d. inverted but not reflected. 32. At a free boundary, waves are a. neither reflected nor inverted. c. reflected and inverted. b. reflected but not inverted. d. inverted but not reflected. 33. How many nodes and antinodes are shown in the standing wave above? a. two nodes and three antinodes c. one-third node and one antinode b. one node and two antinodes d. three nodes and two antinodes 34. What is the fewest number of nodes a standing wave can have? a. 1 c. 3 b. 2 d. 4

35. How many nodes and antinodes are shown in the standing wave above? a. four nodes and four antinodes c. four nodes and five antinodes b. four nodes and three antinodes d. five nodes and four antinodes 36. Sound waves a. are a part of the electromagnetic spectrum. b. do not require a medium for transmission. c. are longitudinal waves. d. are transverse waves. 37. The trough of the sine curve used to represent a sound wave corresponds to a. condensation. b. rarefaction. c. the point where molecules vibrate at a right angle to the direction of wave travel. d. a region of low elasticity. 38. Which of the following is the region of a longitudinal wave in which the density and pressure are greater than normal? a. rarefaction c. spherical wave b. compression d. Doppler effect 39. Which of the following is the region of a longitudinal wave in which the density and pressure are less than normal? a. rarefaction c. spherical wave b. compression d. Doppler effect 40. How high or low we perceive a sound to be, depending on the frequency of the sound wave, is defined as the a. infrasonic wave. c. ultrasonic wave. b. frequency. d. pitch. 41. Which of the following is the number of cycles per unit of time? a. infrasonic wave c. ultrasonic wave b. frequency d. pitch 42. Pitch refers to a. how many vibrations per second are perceived by the human ear. b. how many cycles per second are in a transverse wave. c. the constructive interference of electromagnetic waves. d. the destructive interference in transverse waves. 43. Which of the following has a higher speed of sound? a. helium at 0 C c. copper at 0 C b. air at 0 C d. air at 100 C 44. Which has a higher speed of sound? a. water c. methyl alcohol b. oxygen d. copper 45. Which of the following are series of compressions in graphical representations of spherical and plane waves? a. wavelength c. rays b. source d. wave fronts 46. As a train starts from rest then accelerates down the track, coming toward an observer faster and faster, the frequency of the sound waves coming toward the observer will be a. less than the source frequency. c. stationary. b. constantly increasing in frequency. d. greater than the source frequency.

47. The Doppler effect occurs with a. only sound waves. c. only water waves. b. only compressional waves. d. all waves. 48. As a sound source approaches and then moves past a stationary observer, the observer will hear a. a steady rise in pitch. c. a rise in pitch, then a drop in pitch. b. a sudden drop in pitch. d. a drop in pitch, then a rise in pitch. 49. If you hear the pitch of a siren become lower, you know that a. neither you nor the siren is moving. b. you are moving toward the siren or the siren is moving toward you. c. you are moving away from the siren or the siren is moving toward you. d. the source has just passed you or it is accelerating away from you. 50. The property of sound called intensity is a. proportional to the rate at which sound energy flows through an area normal to the direction of propagation. b. inversely proportional to the rate at which sound energy flows through an area normal to the direction of propagation. c. proportional to the period of a sound wave. d. proportional to the frequency of a sound wave. 51. Tripling the distance from a sound source will change the intensity of the sound waves by what factor? a. c. 3 b. d. 9 52. What is the intensity of sound waves produced by a trumpet at a distance of 1.6 m when the power output of the trumpet is 0.30 W? a. 5.9 10 3 W/m 2 c. 9.4 10 3 W/m 2 b. 1.5 10 2 W/m 2 d. 3.7 10 2 W/m 2 53. If the intensity of a sound is 8.0 10 4 W/m 2 at a distance of 5.0 m, what is the power of the sound? a. 1.2 W c. 0.50 W b. 0.25 W d. 1.6 W 54. If the intensity of a sound is increased by a factor of 100, the new decibel level will be a. two units greater. c. 10 times greater. b. double the old one. d. 20 units greater. 55. A difference in 10 db means the sound is a. twice as loud. c. 100 times as loud. b. 10 times as loud. d. There would be no change in loudness. 56. What is the intensity of a sound wave in relation to the intensity at the threshold of hearing? a. relative intensity c. perceived loudness b. decibel level d. resonance 57. Which of the following is the condition that exists when the frequency of a force applied to a system matches the natural frequency of vibration of the system? a. pitch c. timbre b. decibel level d. resonance 58. What phenomenon is created by two tuning forks side by side that emit frequencies that differ by only a small amount? a. resonance c. the Doppler effect b. interference d. beats 59. Two vibrating tuning forks held side by side will create a beat frequency of what value if the individual frequencies of the two forks are 342 Hz and 345 Hz, respectively? a. 687 Hz c. 339 Hz b. 343.5 Hz d. 3 Hz

60. Two notes have a beat frequency of 8 Hz. The frequency of one note is 612 Hz. What is the frequency of the other note? a. 325 Hz or 318 Hz c. 604 Hz or 620 Hz b. 5 Hz d. 680 Hz Short Answer 61. How is the relationship between period and frequency represented as an equation? 62. Suppose longitudinal simple harmonic waves are generated in a long spring. Describe the motion of a particle within the spring. 63. A boat produces a wave as it passes an aluminum can floating in a lake. Explain why the can is not carried by the wave motion. 64. In the waveform shown above, which letter represents the amplitude of the wave? 65. In the waveform shown above, which letter represents the trough of the wave? 66. In the waveform shown above, what does letter C represent? 67. What determines the pitch of a musical note? 68. What happens to pitch when the frequency of a sound wave increases? 69. Which carries a sound wave more rapidly, a solid or a gas? Explain. 70. When does resonance occur?

Unit 6 Practice Test: Sound Answer Section MULTIPLE GUESS SHORT ANSWER 61. 1. B 31. C 2. C 32. B 3. A 33. D 4. B 34. B 5. D 35. D 6. C 36. C 7. D 37. B 8. B 38. B 9. B 39. A 10. C 40. D 11. B 41. B 12. C 42. A 13. A 43. C 14. C 44. D 15. C 45. D 16. C 46. B 17. A 47. D 18. B 48. C 19. A 49. D 20. B 50. A 21. C 51. A 22. C 52. C 23. C 53. B 24. D 54. D 25. B 55. B 26. D 56. B 27. A 57. D 28. B 58. D 29. A 59. D 30. B 60. C 62. The particle will vibrate continuously along the spring around an equilibrium position with simple harmonic motion. 63. The water wave moves from one place to another, but the water is not carried with it. In other words, the disturbance moves from one location to another, but the medium does not. 64. D 65. B 66. wavelength 67. frequency 68. The pitch rises. 69. A solid carries a sound wave more rapidly because its molecules are closer together than those of a gas. 70. Resonance is produced when a forced vibration is the same as the natural frequency of an object.

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