sound pressure, power and loudness
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Transcript sound pressure, power and loudness
MUSICAL ACOUSTICS
SOUND
PRESSURE,
POWER AND
LOUDNESS
Science of Sound
Chapter 6
DECIBEL SCALES
4 Decibel Scale (Tracks 8-10)
FREE FIELD
I = W/4πr2
at r = 1 m:
LI = 10 log I/10-12
= 10 log W/10-12 – 10 log 4p
= LW - 11
)
HEMISPHERICAL
FIELD
I = W/2pr2
at r = l m
LI = LW - 8
Note that the intensity I
1/r2 for both free and
hemispherical fields;
therefore, LI decreases 6 dB for each doubling of distance
)
4 Decibel scale (free-field speech Track 11
SOUND PRESSURE LEVEL
Our ears respond to extremely small pressure
fluctuations p
Intensity of a sound wave is proportional to the sound
Pressure squared:
ρc ≈ 400
I = p2 /ρc
ρ = density
c = speed of sound
We define sound pressure level:
Lp = 20 log p/p0
(or SPL)
p0 = 2 x 10-5 Pa (or N/m2)
TYPICAL SOUND LEVELS
MULTIPLE SOURCES
Example:Two
uncorrelated
sources of 80
dB each will
produce a
sound level of
83dB
(Not 160 dB)
MULTIPLE SOURCES
What we really want to add are mean-square
average pressures (average values of p2)
This is equivalent to adding intensities
Example: 3 sources of 50 dB each
Lp = 10 log [(P12+P22+P32)/P02] = 10 log (I1 + I2 + I3)/ I0)
= 10 log I1/I0 + 10 log 3 = 50 + 4.8 = 54.8 dB
SOUND PRESSURE and INTENSITY
Sound pressure level is measured with a sound level meter (SLM)
Sound intensity level is more difficult to measure, and it requires
more than one microphone
In a free field, however, LI ≈ LP
FOUR ATTRIBUTES USED TO DESCRIBE A SOUND:
•Loudness
•Pitch
•Timbre
•Duration
EACH OF THESE DEPENDS ON ONE OR MORE PHYSICAL
PARAMETERS THAT CAN BE MEASURED:
•Sound pressure
•Frequency
•Spectrum
•Duration (measured)
•Envelope
Relating the SUBJECTIVE QUALITIES to the PHYSICAL
PARAMETERS that we can MEASURE OBJECTIVELY
Is an important problem in PSYCHOACOUSTICS
DEPENDENCE OF SUBJECTIVE QUALITIES OF
SOUND ON PHYSICAL PARAMETERS
LOUDNESS LEVEL
Contours of equal loudness are labeled phons
At 1000 Hz, Loudness Level = Lp
PLOT YOUR OWN FREQUENCY RESPONSE
ASSIGNMENT: Plot your own frequency
response curves by using
www.phys.unsw.edu.au/~jw/hearing.html
HOW DOES
LOUDNESS
DEPEND ON
FREQUENCY?
7 Loudness scaling
(Tracks 19-20)
LOUDNESS SCALING
7 Loudness scaling (Track 19,20)
LOUDNESS RESPONSE OF THE EAR
LOUDNESS OF COMPLEX TONES
Loudness depends mainly on
SOUND PRESSURE.
but it also depends on FREQUENCY,
SPECTRUM and DURATION
DEPENDENCE
OF
LOUDNESS
ON
BANDWIDTH
CRITICAL
BANDS
8 Critical bands by loudness comparison
Track 7
LOUDNESS OF COMBINED SOUNDS
JUST NOTICEABLE LEVEL DIFFERENCE
LEVEL INCREMENT NEEDED TO DOUBLE LOUDNESS
RANGE OF FREQUENCY AND INTENSITY
OF THE EAR
MUSICAL DYNAMICS AND LOUDNESS
9 Asymmetry of masking (Track 22)
HOW DOES
LOUDNESS
DEPEND ON
PARTIAL
MASKING?
HOW DOES LOUDNESS DEPEND ON DURATION?
8 Temporal integration (Track 21)
LOUDNESS RECRUITMENT
UNUSUALLY RAPID GROWTH OF LOUDNESS
ABOVE A CERTAIN THRESHOLD
GENERALLY ASSOCIATED WITH HEARING LOSS,
BUT NORMAL LISTENERS EXPERIENCE IT FOR
TONES OF VERY HIGH OR VERY LOW FREQUENCY
MONAURAL vs BINAURAL LOUDNESS
FOR SOFT SOUNDS (~20dB) BINAURAL
LOUDNESS EXCEEDS MONAURAL LOUDNESS
BY A FACTOR OF 2
(CORRESPONDS TO ΔL = 8dB)
FOR LOUD SOUNDS (~80dB) BINAURAL
LOUDNESS EXCEEDS MONAURAL
LOUDNESS BY A FACTOR ~/.4
(CORRESPONDS TO ΔL = 6dB)
Zwicker & Fastl (1990)
INTENSITY DISCRIMINATION AND CODING
AT LOW LEVELS, INTENSITY CHANGES CAN BE
SIGNALLED BOTH BY CHANGES IN FIRING RATES OF
NEURONS AT THE CENTER OF THE EXCITATION
PATTERN AND BY THE SPREADING OF THE EXCITATION
PATTERN (TO INCLUDE MORE NEURONS)
AT HIGH LEVELS, MOST NEURONS AT THE CENTER OF
THE EXCITATION PATTERN ARE SATURATED, BUT
INTENSITY CHANGES ARE SIGNALLED BY CHANGES
IN FIRING RATES AT THE EDGES.
AN INCREASE IN LEVEL ALSO MAY BE SIGNALLED
BY INCREASED PHASE LOCKING TO THE TONE WHICH
RESULTS IN TEMPORAL REGULARITY OF
NEURAL FIRINGS