Presentation is loading. Please wait.

Presentation is loading. Please wait.

Chapter 15 Properties of Sound Pitch and Loudness Sound Intensity Level Doppler Effect.

Published byLinette Hines Modified over 8 years ago

Similar presentations

Presentation on theme: "Chapter 15 Properties of Sound Pitch and Loudness Sound Intensity Level Doppler Effect."— Presentation transcript:

1 Chapter 15 Properties of Sound Pitch and Loudness Sound Intensity Level Doppler Effect

2 Sound Sound is a longitudinal mechanical wave. Sound is a longitudinal mechanical wave. Compressions(High Pressure) Compressions(High Pressure) Rarefactions(Low Pressure) Rarefactions(Low Pressure)

3 Speed of Sound Depends on the medium. Depends on the medium. The more elastic the medium the faster sound will travel through it. The more elastic the medium the faster sound will travel through it. Speed in metals>speed in water>speed in air Speed in metals>speed in water>speed in air Sound can’t travel through vacuum. Sound can’t travel through vacuum.

4 Speed of Sound in Air v = 331 + 0.6 T ( in meters/sec) T is the temperature in 0 C. T is the temperature in 0 C. In higher humidity, sound will travel faster. In higher humidity, sound will travel faster.

5 Properties of Sound Share general properties of other waves Share general properties of other waves Reflection (Echoes) – Echolocation, SONAR Reflection (Echoes) – Echolocation, SONAR Refraction Refraction Interference – “dead spots” at nodes Interference – “dead spots” at nodes Diffraction – hearing someone around a corner Diffraction – hearing someone around a corner

6 Doppler Effect The change in a wave's perceived frequency due to the motion of either the sound source or the observer. The change in a wave's perceived frequency due to the motion of either the sound source or the observer. All waves Doppler shift All waves Doppler shift Applications – Radar (baseballs, cars), distances of galaxies, heart beats during ultrasounds Applications – Radar (baseballs, cars), distances of galaxies, heart beats during ultrasounds Austrian physicist Christian Doppler (1803-1853). Austrian physicist Christian Doppler (1803-1853). Demonstrations Demonstrations Doppler Ball Doppler Ball Train sound clip Train sound clip Train sound clip Train sound clip Simulations Simulations physlet animation physlet animation physlet animation physlet animation http://www.walter-fendt.de/ph14e/dopplereff.htm http://www.walter-fendt.de/ph14e/dopplereff.htm http://www.walter-fendt.de/ph14e/dopplereff.htm

7 Doppler Effect

8 When a sound source moves towards the observer, the detected frequency is higher. When a sound source moves towards the observer, the detected frequency is higher. When the sound source moves away from the observer, the detected frequency is lower. When the sound source moves away from the observer, the detected frequency is lower. Can occur if the observer is moving and the source is stationary. Can occur if the observer is moving and the source is stationary.

9 The Doppler Effect http://www.physicsclassroom.com/Class/sound/u11l3b.cfm

10 Doppler Effect f d = Detected Frequency f : frequency of source f : frequency of source v : speed of sound v : speed of sound v o : speed of observer v o : speed of observer (+)when observer moving towards source v s : speed of source v s : speed of source (-)when source is moving towards observer

11 Example 1 An ambulance is approaching a stationary observer. The siren of the ambulance emits a frequency of 480Hz and the speed of the ambulance is 50km/h(=13.88m/s). What frequency will the stationary observer hear when the ambulance is approaching? Assume T=20 o C. An ambulance is approaching a stationary observer. The siren of the ambulance emits a frequency of 480Hz and the speed of the ambulance is 50km/h(=13.88m/s). What frequency will the stationary observer hear when the ambulance is approaching? Assume T=20 o C. Answer: f d = 500Hz Answer: f d = 500Hz

12 Shock Waves Shock Waves When the speed of a moving object is greater than the speed of the wave, the wave fronts pile up and produce a high pressure ridge similar to the wave created by the bow of a ship. When the speed of a moving object is greater than the speed of the wave, the wave fronts pile up and produce a high pressure ridge similar to the wave created by the bow of a ship. physlet animation physlet animation

13

14 Sonic Boom Sonic Boom When the pressure ridge of a bow wave of a jet passes over an observer on the ground, the observer experiences a sonic boom.

15 Pitch: the frequency of a sound wave. Musical notes have a given pitch. Musical notes have a given pitch. The note C has a frequency of 262 Hz. The note C has a frequency of 262 Hz. When two notes differ by a ratio of 2:1 they are one octave apart. Different notes have different ratios of frequencies When two notes differ by a ratio of 2:1 they are one octave apart. Different notes have different ratios of frequencies What would be the next higher C and next lower C? What would be the next higher C and next lower C? Ans: 524 Hz, 131 Hz Ans: 524 Hz, 131 Hz

16 Sound Intensity (I) Energy transmitted by a wave in a given time over a given area. I = (Power transmitted by the Wave)/Area SI unit - Watts/m 2 SI unit - Watts/m 2 Threshold of human hearing: I o =1 x 10 -12 Watts/m 2 Threshold of human hearing: I o =1 x 10 -12 Watts/m 2 Threshold of Pain: Threshold of Pain: I P = 1 Watts/m 2

17 Loudness Related to intensity but it’s a sensation in the mind of a human being Related to intensity but it’s a sensation in the mind of a human being Presumably because of the wide range of intensities detected, what we perceive as loudness is not directly proportional to the intensity. Presumably because of the wide range of intensities detected, what we perceive as loudness is not directly proportional to the intensity. 10 dB increase is heard as being twice as loud. 10 dB increase is heard as being twice as loud.

18 Sound Level A measure of our perception of the loudness of the sound. A measure of our perception of the loudness of the sound. Based on logarithmic scale Based on logarithmic scale Unit: decibel(dB) Unit: decibel(dB)

19 Sound Level, (decibel) β – measured in decibels β – measured in decibels The decibel compares the sound intensity (I), to I o (1 x 10 -12 Watts/m 2 ), the threshold of human hearing. The decibel compares the sound intensity (I), to I o (1 x 10 -12 Watts/m 2 ), the threshold of human hearing. An increase in 10 decibel is 10x as intense, 20 dB increase is 100x as intense. An increase in 10 decibel is 10x as intense, 20 dB increase is 100x as intense. Remember: log(10 x )= x Remember: log(10 x )= x x = log y is the same as y = 10 x x = log y is the same as y = 10 x

20 Examples of Sound Intensity Levels jet plane taking off140 dB jet plane taking off140 dB air raid siren125 dB air raid siren125 dB threshold of pain120 dB threshold of pain120 dB loud rock music115 dB loud rock music115 dB ear damage starts 85 dB ear damage starts 85 dB busy traffic 70 dB busy traffic 70 dB normal conversation 60 dB normal conversation 60 dB quiet library 40 dB quiet library 40 dB soft whisper 20 dB soft whisper 20 dB threshold of human hearing 0 dB threshold of human hearing 0 dB

21 Example 2 What is the sound level (decibel) of a sound of 10 -4 W/m 2 intensity ? What is the sound level (decibel) of a sound of 10 -4 W/m 2 intensity ? Answer: 80dB Answer: 80dB

22 Example 3 How many times louder is a quiet library sound (40 dB) compared to a soft whisper (20 dB)? How many times louder is a quiet library sound (40 dB) compared to a soft whisper (20 dB)? Hint 1: Property of logs: log(A/B) = logA –logB Hint 1: Property of logs: log(A/B) = logA –logB Hint 2: Take the difference in dB and then find (I 2 /I 1 ) Hint 2: Take the difference in dB and then find (I 2 /I 1 ) Answer: (I 2 /I 1 )= 100/1 Answer: (I 2 /I 1 )= 100/1

Download ppt "Chapter 15 Properties of Sound Pitch and Loudness Sound Intensity Level Doppler Effect."

Similar presentations

Waves & Sound A. Waves 1. The nature of waves

Waves & Sound A. Waves 1. The nature of waves
Chapter 12 Sound. What is sound? Sound is a compressional wave which travels through the air through a series of compressions and rarefactions.

Chapter 12 Sound. What is sound? Sound is a compressional wave which travels through the air through a series of compressions and rarefactions.
Sound Chapter 16.

Sound Chapter 16.
Chapter 13 Sound Properties of Sound – the source of all sound waves is vibration  Sound waves – longitudinal waves – the particles in the medium are.

Chapter 13 Sound Properties of Sound – the source of all sound waves is vibration  Sound waves – longitudinal waves – the particles in the medium are.
Principles of Physics. Sound Result of vibration of air particles around a source Longitudinal wave – air particles get compressed and spread apart as.

Principles of Physics. Sound Result of vibration of air particles around a source Longitudinal wave – air particles get compressed and spread apart as.
Sound Pitch Loudness Beats Doppler Effect

Sound Pitch Loudness Beats Doppler Effect
Sound Pitch Loudness Sound Intensity Level Doppler Effect Physics Mrs. Coyle.

Sound Pitch Loudness Sound Intensity Level Doppler Effect Physics Mrs. Coyle.
Sound. Sound Waves  Sound waves are longitudinal waves.  The source of a sound wave is a vibrating object.  Only certain wavelengths of longitudinal.

Sound. Sound Waves  Sound waves are longitudinal waves.  The source of a sound wave is a vibrating object.  Only certain wavelengths of longitudinal.
Sound Waves Physics Chapter 13 Section 1. I. Production of sound waves Produced by an object vibrating Produced by an object vibrating -ex. Tuning fork.

Sound Waves Physics Chapter 13 Section 1. I. Production of sound waves Produced by an object vibrating Produced by an object vibrating -ex. Tuning fork.
All sounds are produced by the vibration of matter. If there is no vibration, there is no sound.

All sounds are produced by the vibration of matter. If there is no vibration, there is no sound.
What is a sound wave? Mechanical wave – longitudinal *A vibration *Particles of medium are disturbed *Causes a wave causes Most common medium is air Can.

What is a sound wave? Mechanical wave – longitudinal *A vibration *Particles of medium are disturbed *Causes a wave causes Most common medium is air Can.
SOUND WAVE PROPERTIES Sound longitudinal Sound is a longitudinal (Mechanical)wave caused by a vibrating object Molecules collide, producing sound Examples:

SOUND WAVE PROPERTIES Sound longitudinal Sound is a longitudinal (Mechanical)wave caused by a vibrating object Molecules collide, producing sound Examples:
SOUND A vibrating object, such as your voice box, stereo speakers, guitar strings, etc., creates longitudinal waves in the medium around it. When these.

SOUND A vibrating object, such as your voice box, stereo speakers, guitar strings, etc., creates longitudinal waves in the medium around it. When these.
Compressional Waves.  Requires a medium for propagation.  Compression of molecules transmit sound.

Compressional Waves.  Requires a medium for propagation.  Compression of molecules transmit sound.
Sound Chapter 15. Topics for Sound Sound wave propertiesSound wave properties Speed of soundSpeed of sound EchoesEchoes BeatsBeats Doppler shiftDoppler.

Sound Chapter 15. Topics for Sound Sound wave propertiesSound wave properties Speed of soundSpeed of sound EchoesEchoes BeatsBeats Doppler shiftDoppler.
Sound Chapter 17. Wave fronts In a flat region of space, spherical wave fronts are near planar.

Sound Chapter 17. Wave fronts In a flat region of space, spherical wave fronts are near planar.
Chapter 12 Sound.

Chapter 12 Sound.
Sound. Speed of sound in solids, liquids, and gases Speed of sound in gas (air): 344 m/sec. Speed of sound in liquid (water): 1100 m/sec Speed of sound.

Sound. Speed of sound in solids, liquids, and gases Speed of sound in gas (air): 344 m/sec. Speed of sound in liquid (water): 1100 m/sec Speed of sound.
~ Nature of Sound ~ 1. What is sound? 2. Human Hearing

~ Nature of Sound ~ 1. What is sound? 2. Human Hearing
Chapter 12 Sound. 12-1 Characteristics of Sound Sound can travel through any kind of matter, but not through a vacuum. The speed of sound is different.

Chapter 12 Sound Characteristics of Sound Sound can travel through any kind of matter, but not through a vacuum. The speed of sound is different.

Similar presentations

Ads by Google