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1
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2
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3
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4
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5
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- Pulsive sources: ballons, blank pistol
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6
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7
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- Cheap electret mikes in the ear ducts
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8
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- A loudspeaker is fed with a special test signal x(t), while a microphone
records the room response
- A proper deconvolution technique is required for retrieving the impulse
response h(t) from the recorded signal y(t)
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9
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- The desidered result is the linear impulse response of the acoustic
propagation h(t). It can be recovered by knowing the test signal x(t)
and the measured system output y(t).
- It is necessary to exclude the effect of the not-linear part K and of
the background noise n(t).
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10
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- Different types of test signals have been developed, providing good
immunity to background noise and easy deconvolution of the impulse
response:
- MLS (Maximum Lenght Sequence, pseudo-random white noise)
- TDS (Time Delay Spectrometry, which basically is simply a linear sine
sweep, also known in Japan as “stretched pulse” and in Europe as
“chirp”)
- ESS (Exponential Sine Sweep)
- Each of these test signals can be employed with different deconvolution
techniques, resulting in a number of “different” measurement methods
- Due to theoretical and practical considerations, the preference is
nowadays generally oriented for the usage of ESS with not-circular
deconvolution
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11
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- MLSSA was the first apparatus for measuring impulse responses with MLS
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12
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- The Italian-made CLIO system has superseded MLSSA for most
electroacoustics applications (measurement of loudspeakers, quality
control)
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13
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- Techron TEF 10 was the first apparatus for measuring impulse responses
with TDS
- Subsequent versions (TEF 20, TEF 25) also support MLS
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14
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15
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16
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17
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18
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- X(t) is a periodic binary signal obtained with a suitable
shift-register, configured for maximum lenght of the period.
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19
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- The re-recorded signal y(i) is cross-correlated with the excitation
signal thanks to a fast Hadamard transform. The result is the required
impulse response h(i), if the system was linear and time-invariant
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20
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21
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22
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- x(t) is a band-limited sinusoidal
sweep signal, which frequency is varied exponentially with time,
starting at f1 and ending at f2.
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23
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24
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- The not-linear behaviour of the loudspeaker causes many harmonics to
appear
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25
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- The deconvolution of the IR is obtained convolving the measured signal
y(t) with the inverse filter z(t) [equalized, time-reversed x(t)]
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26
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- The “time reversal mirror” technique is employed: the system’s impulse
response is obtained by convolving the measured signal y(t) with the
time-reversal of the test signal x(-t). As the log sine sweep does not
have a “white” spectrum, proper equalization is required
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27
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- The last impulse response is the linear one, the preceding are the
harmonics distortion products of various orders
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28
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29
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30
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- The initial approach was to use directive microphones for gathering some
information about the spatial properties of the sound field “as
perceived by the listener”
- Two apparently different approaches emerged: binaural dummy heads and
pressure-velocity microphones:
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31
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- It was attempted to “quantify” the “spatiality” of a room by means of
“objective” parameters, based on 2-channels impulse responses measured
with directive microphones
- The most famous “spatial” parameter is IACC (Inter Aural Cross
Correlation), based on binaural IR measurements
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32
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- Other “spatial” parameters are the Lateral Energy ratio LF
- This is defined from a 2-channels impulse response, the first channel is
a standard omni microphone, the second channel is a “figure-of-eight”
microphone:
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33
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- Experiment performed in anechoic room - same loudspeaker, same source
and receiver positions, 5 binaural dummy heads
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34
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- Diffuse field - huge difference among the 4 dummy heads
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35
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- Experiment performed in the Auditorium of Parma - same loudspeaker, same
source and receiver positions, 4 pressure-velocity microphones
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36
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- At 25 m distance, the scatter is really big
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37
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38
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- The Soundfield microphone allows for simultaneous measurements of the
omnidirectional pressure and of the three cartesian components of
particle velocity (figure-of-8 patterns)
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39
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- The original idea of Michael Gerzon was finally put in practice in 2003,
thanks to the Israeli-based company WAVES
- More than 50 theatres all around the world were measured, capturing 3D
IRs (4-channels B-format with a Soundfield microphone)
- The measurments did also include binaural impulse responses, and a
circular-array of microphone positions
- More details on WWW.ACOUSTICS.NET
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40
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41
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- Microphone arrays capable of synthesizing aribitrary directivity
patterns
- Advanced spatial analysis of the sound field employing spherical
harmonics (Ambisonics - 1° order or higher)
- Loudspeaker arrays capable of synthesizing arbitrary directivity
patterns
- Generalized solution in which both the directivities of the source and
of the receiver are represented as a spherical harmonics expansion
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42
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43
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- The answer is simple: analyze the spatial distribution of both source
and receiver by means of higher-order spherical harmonics expansion
- Spherical harmonics analysis is the equivalent, in space domain, of the
Fourier analysis in time domain
- As a complex time-domain waveform can be though as the sum of a number
of sinusoidal and cosinusoidal functions, so a complex spatial
distribution around a given notional point can be expressed as the sum
of a number of spherical harmonic functions
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44
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45
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- Arnoud Laborie developed a 24-capsule compact microphone array - by
means of advanced digital filtering, spherical ahrmonic signals up to 3°
order are obtained (16 channels)
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46
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- Jerome Daniel and Sebastien Moreau built samples of 32-capsules
spherical arrays - these allow for extractions of microphone signals up
to 4° order (25 channels)
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47
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- Sebastien Moreau and Olivier Warusfel verified the directivity patterns
of the 4°-order microphone array in the anechoic room of IRCAM (Paris)
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48
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- Current 3D IR sampling is still based on the usage of an
“omnidirectional” source
- The knowledge of the 3D IR measured in this way provide no information
about the soundfield generated inside the room from a directive source
(i.e., a musical instrument, a singer, etc.)
- Dave Malham suggested to represent also the source directivity with a
set of spherical harmonics, called O-format - this is perfectly
reciprocal to the representation of the microphone directivity with the
B-format signals (Soundfield microphone).
- Consequently, a complete and reciprocal spatial transfer function can be
defined, employing a 4-channels O-format source and a 4-channels
B-format receiver:
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49
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- LookLine D200 dodechaedron
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50
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- Adrian Freed, Peter Kassakian, and David Wessel (CNMAT) developed a new
120-loudspeakers, digitally controlled sound source, capable of
synthesizing sound emission according to spherical harmonics patterns up
to 5° order.
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51
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- Class-D embedded amplifiers
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52
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- The spatial reconstruction error of a 120-loudspeakers array is
frequency dependant, as shown here:
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53
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- Employing massive arrays of transducers, it will be feasible to sample
the acoustical temporal-spatial transfer function of a room
- Currently available hardware and software tools make this practical only
up to 4° order, which means 25 inputs and 25 outputs
- A complete measurement for a given source-receiver position pair takes
approximately 10 minutes (25 sine sweeps of 15s each are generated one
after the other, while all the microphone signals are sampled
simultaneously)
- However, it has been seen that real-world sources can be already
approximated quite well with 2°-order functions, and even the human HRTF
directivites are reasonally approximated with 3°-order functions.
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54
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- The sine sweep method revealed to be systematically superior to the MLS
method for measuring electroacoustical impulse responses
- Traditional methods for measuring “spatial parameters” (IACC, LF) proved
to be unreliable and do not provide complete information
- The 1°-order Ambisonics method can be used for generating and recording
sound with a limited amount of spatial information
- For obtaining better spatial resolution, High-Order Ambisonics can be
used, limiting the spherical-harmonics expansion to a reasonable order
(2°, 3° or 4°).
- Experimental hardware and software tools have been developed (mainly in
France, but also in USA), allowing to build an inexpensive complete
measurement system
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Notes
