auditory neuroscience - lecture 1 the nature of sound [email protected]...
TRANSCRIPT
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Auditory Neuroscience - Lecture 1
The Nature of Sound
auditoryneuroscience.com/lectures
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1: Sound Sources
Why and how things vibrate
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● Physical objects which have both spring-like stiffness and inert mass (“spring-mass systems”) like to vibrate.
● Higher stiffness leads to faster vibration.
● Higher mass leads to slower vibration.
“Simple Harmonic Motion”
● http://auditoryneuroscience.com/acoustics/simple_harmonic_motion
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The Cosine and its Derivatives
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Modes of Vibration
http://auditoryneuroscience.com/acoustics/modes-vibration-2-d
http://auditoryneuroscience.com/acoustics/modes_of_vibration
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Overtones & Harmonics
The note B3 (247 Hz) played by a Piano and a Bell
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Damping
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g lockensp ie l
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castane t
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2: Describing Vibrations Mathematically
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Making a Triangle Wave from Sine Waves (“Fourier Basis”)
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Making a Triangle Wavefrom Impulses (“Nyquist Basis”)
x(t)= -δ(0)… -2/3 δ(1 π/5)… -1/3 δ(2 π/5)… +1/3 δ(3 π/5)… +2/3 δ(4 π/5)… +3/3 δ(5 π/5)… + …
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Fourier Synthesis of a Click
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The Effect of Windowing on a Spectrum
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Time-Frequency Trade-off
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Spectrograms with Short or Long Windows
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3: Impulse responses, linear filters and voices
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Impulse Responses (Convolution)
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Convolution with “Gammatone Filter”
input (FM sweep)
gamma tone filter
output ("convolution")
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Click Trains, Harmonics and Voices
http://auditoryneuroscience.com/vocal_folds
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Low and High Pitched Voices
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4: Sound Propagation
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Sound Propagation
http://auditoryneuroscience.com/acoustics/sound_propagation
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The Inverse Square Law
● Sound waves radiate out from the source in all directions.
● They get “stretched” out as the distance from the source increases.
● Hence sound intensity is inversely proportional to the square of the distance to the source.
● http://auditoryneuroscience.com/acoustics/inverse_square_law
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Velocity and Pressure Waves
Pressure (P) is proportional to force (F) between adjacent sound particles.
Let a sound source emit a sinusoid.
F = m ∙ a = m ∙ dv/dt = b ∙ cos(f ∙ t)
v = ∫ b/m cos(f ∙ t) dt = b/(f ∙ m) sin(f ∙ t)
Hence particle velocity and pressure are 90 deg out of phase (pressure “leads”) but proportional in amplitude
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5: Sound Intensity, dB Scales and Loudness
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Sound PressureSound is most commonly referred to as a
pressure wave, with pressure measured in μPa. (Microphones usually measure pressure).
The smallest audible sound pressure is ca 20 μPa (for comparison, atmospheric pressure is 101.3 kPa, 5 billion times larger).
The loudest tolerable sounds have pressures ca 1 million times larger than the weakest audible sounds.
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The Decibel Scale
Large pressure range usually expressed in “orders of magnitude”.
1,000,000 fold increase in pressure = 6 orders of magnitude = 6 Bel = 60 dB.
dB amplitude:y dB = 10 log(x/xref)0 dB implies x=xref
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Pressure vs Intensity (or Level)Sound intensities are more commonly reported than
sound amplitudes.
Intensity = Power / unit area.
Power = Energy / unit time, is proportional to amplitude2.
(Kinetic energy =1/2 m v2, and pressure, velocity and amplitude all proportional to each other.)
dB intensity:1 dB = 10 log((p/pref)2) = 20 log(p/pref)
dB SPL = 20 log(x/20 μPa)
Weakest audible sound: 0 dB SPL.
Loudest tolerable sound: 120 dB SPL.
Typical conversational sound level: ca 70 dB SPL
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dB SPL and dB A
• Iso-loudness contours• A-weighting filter (blue)
Image source: wikipedia
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dB HL (Hearing Level)Threshold level of auditory sensation measured
in a subject or patient, above “expected threshold” for a young, healthy adult.
-10 - 25 dB HL: normal hearing
25 - 40 dB HL: mild hearing loss
40 - 55 dB HL: moderate hearing loss
55 - 70 dB HL: moderately severe hearing loss
70 – 90 dB HL: severe hearing loss
> 90 dB HL: profound hearing loss
http://auditoryneuroscience.com/acoustics/clinical_audiograms