Post on 26-Dec-2015
The ear and perception of sound(Psychoacoustics)
Updated 2013Aug05
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Outline
A. Structure of the Ear
B. Perception of Pitch
C. Perception of Loudness
D. Timbre (quality of sound)
E. References
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Introduction
Psychoacoustics
is the study of
subjective human perception
of sounds.
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A. The Structure of the Ear
The length of the auditory canal has been greatly exaggerated
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A.1 Outer Ear Amplifies Sound
Auditory canal is a resonator at approximately 2000 to 5000 Hertz.
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A.2 The Middle Ear•The bones (ossicles) of the middle ear form a lever which “amplifies” the displacement by a factor of 3x.
•The stirrup transfers the force to the much smaller area of the oval window, resulting in 10 to 30 x increase in pressure level
•Overall the sound is amplified by as much as 1000x or 30 dB
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A.3 Inner Ear Senses Sound
Reference: http://hyperphysics.phy-astr.gsu.edu/hbase/sound/place.html#c1
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Over 20,000 hair cells!
B. Perception of Pitch
1. Range of Hearing
2. Pitch Discrimination and jnd
3. Combination tones
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1a Range of Hearing
Humans can hear from 16 to 20,000 Hertz(In terms of music, this is about 10 octaves)Piano only goes from 27.5 to 4186 Hertz
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1b Test Hearing
• High Frequency Test
• http://audiocheck.net/audiotests_frequencycheckhigh.php
• Low Frequency Test
• http://audiocheck.net/audiotests_frequencychecklow.php
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2a. Pitch Discrimination
• At 1000 Hz, the “jnd” is about 1 Hz (0.1%)
• At 4000 Hz, the “jnd” is about 10 Hz (0.25%)
• Above 10,000 Hz, our discrimination is terrible.(Most music is in range of 30 to 4000 Hertz)
• We can distinguish approximately 5000 different tones
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2b. Beats• Two tones closer than 15 Hertz we hear as a “fused”
tone (average of frequencies) with a “beat”.
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Demo: http://www.phys.unsw.edu.au/jw/beats.html#sounds
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3. Combination Tones
• When tones are far enough apart we hear them as two distinct tones
• We also hear differenceand sum tones thatare not really there(Tartini Tones 1714)
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Demo: http://www.phys.unsw.edu.au/jw/beats.html#Tartini
C. Perception of Loudness
1. Fechner’s law and decibel scale
2. Discrimination (jnd)
3. Threshold of hearing
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1. Which sounds half as loud as first?• Reference: http://www.phys.unsw.edu.au/jw/dB.html
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1b. Decibels: Fechner’s Law
• 1860 Fechner’s Law
• As stimuli are increased by multiplication, sensations increase by addition (Sensation grows as the logarithm of the stimulus)
• Example: A 10x bigger intensity sound is “heard” as only 2x bigger by the ear
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Gustav Theodor Fechner(1801-1887)
1c. Decibel Scale
• The decibel is a logarithmic scale
• A multiplicative factor of 10x in intensity is +10 db
• 0 db is threshold of hearing• 1 db is just noticeable difference• 15 db is a whisper• 60 db is talking• 120 db is maximum safe level• 150 db is jet engine (ear damage)• 180 db stun grenade
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==================Power Ratio dB___________________0.5 -31 02 +35 +710 1020 1350 17100 201000 3010000 40==================
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10m
W atts
IntensityLogdB
2a. JND: Just Noticeable Difference is 1dB• Reference: http://www.phys.unsw.edu.au/jw/dB.html
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2b Discrimination of Loudness
• jnd = “just noticeable difference”
• The ear’s “jnd” for Loudness is approximately 1 dB
• Or, sound must be 30% louder in intensity for us to just notice that it is louder.
• This depends somewhat on frequency (pitch) and loudness (intensity). We have trouble distinguishing changes in loudness for very the very loud or the very soft sounds
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2c. Smaller than JND (7% change)• Reference: http://www.phys.unsw.edu.au/jw/dB.html
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3a. Threshold of Hearing & Age (Presbycusis)
Note “Sound Pressure dB” (or SPLdB) is approximately half regular “energy” decibels (dB).
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3b. Hearing Threshold
• The ear can hear as small as 10-12 Watts/m2
(one trillionth of a watt per square meter)( 0.000,000,000,001 Watt/m2 )
• Example: you might be able to hear someone talking half a mile away under ideal circumstances
• Intensity is proportional to thesquare of the pressure amplitudeMinimum ear can hear is 0.000,02 Pascals(Atmospheric pressure is 100,000 Pascal)
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D. Timbre
1. Waveforms and Timbre
2. Fourier Theory
3. Ohm’s law of acoustics
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1. Waveform Sounds
Different “shape” of wave has different “timbre” quality
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Sine Wave (flute)
Square (clarinet)
Triangular (violin)
Sawtooth (brass)
1b. Waveforms of Instruments
• Helmholtz resonators (e.g. blowing on a bottle) make a sine wave
• As the reed of a Clarinet vibrates it open/closes the air pathway, so its either “on” or “off”, a square wave (aka “digital”).
• Bowing a violin makes a kink in the string, i.e. a triangular shape.
• Brass instruments have a “sawtooth” shape.
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2a. Fourier’s Theorem
Any periodic waveform can be constructed from harmonics.
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Joseph Fourier1768-1830
2b. FFT: Fast Fourier Transform
• A device which analyzes any (periodic) waveform shape, and immediately tells what harmonics are needed to make it
• Sample output:tells you its mostly10 k Hertz, witha bit of 20k, 30k, 40k,etc.
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2c. FFT of a Square Wave
• Amplitude “A”
• Contains only odd harmonics “n”
• Amplitude of “n” harmonic is:
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Ab
n
bbn
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1
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2d. FFT of a Sawtooth Wave
• Amplitude “A”
• Contains all harmonics “n”
• Amplitude of “n” harmonic is:
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Ab
n
bbn
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2e. FFT of a triangular Wave
• Amplitude “A”
• Contains ODD harmonics “n”
• Amplitude of “n” harmonic is:
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?4
1
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Ab
n
bbn
3a. Ohm’s Law of Acoustics 31
• 1843 Ohm's acoustic lawa musical sound is perceived by the ear as a set of a number of constituent pure harmonic tones, i.e. acts as a “Fourier Analyzer”
Georg Simon Ohm (1789 – 1854)
Octave, in phase
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For example:, the ear does not really “hear” the combined waveform (purple above), it “hears” both notes of the octave, the low and the high individually.
3b. Ohm’s Acoustic Phase Law 32
• Hermann von Helmholtz elaborated the law (1863?) into what is often today known as Ohm's acoustic law, by adding that the quality of a tone depends solely on the number and relative strength of its partial simple tones, and not on their relative phases.
Hermann von Helmholtz(1821-1894)
The combined waveform here looks completely different, but the ear hears it as the same, because the only difference is that the higher note was shifted in phase.
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3c. Ohm’s Acoustic Phase Law 33
• Hence Ohm’s acoustic law favors the “place” theory of hearing over the “telephone” theory.
• Review:– The “telephone theory” of hearing (Rutherford,
1886) would suggest that the ear is merely a microphone which transmits the total waveform to the brain where it is decoded.
– The “place” theory” of hearing (Helmholtz 1863, Georg von Békésy’s Nobel Prize): different pitches stimulate different hairs on the basilar membrane of the cochlea.
E. Notes/References• http://en.wikipedia.org/wiki/Weber-Fechner_law• http://www.phys.unsw.edu.au/jw/dBNoFlash.html• http://www.phys.unsw.edu.au/jw/uncertainty.html• http://www.phys.unsw.edu.au/jw/beats.html• http://audiocheck.net/audiotests_frequencycheckhigh.php• http://audiocheck.net/audiotests_frequencychecklow.php• Fourier Applet (waveforms) http://www.falstad.com/fourier/
• http://www.music.sc.edu/fs/bain/atmi02/hs/index-audio.html
• Load Error on this page? http://www.music.sc.edu/fs/bain/atmi02/wt/index.html
• FFT of waveforms: http://beausievers.com/synth/synthbasics/
• Demos:• http://www.isvr.soton.ac.uk/SPCG/Tutorial/Tutorial/Tutorial_files/Web-
hearing-Shepard.htm
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