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1
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- Angelo Farina1, Fabio Bozzoli1, Patricia Strasser2
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2
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- Evaluation of the acoustical confort inside a car, in terms of speech
intellegibility
- Objective rating of both electroacoustical devices (sound system) and of
natural communication between passengers
- Evaluation of the bi-directional performances of hands-free
communication systems
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3
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4
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5
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- It is possible to derive the MTF values from a single impulse response
measurement:
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6
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- If the background noise is superposed to the impulse response, the
previous method already takes care of it, and the MTF values are
measured correctly
- However, in some cases, it is advisable to perform a noise-free
measurement of the IR, and then insert the effect of the noise with the
following expression:
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7
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- A Cortex head and torso simulator was selected, after careful
comparative tests performed in an anechoic chamber, which demonstrated
its superiority to other binaural microphones (Neumann, B&K, Head
Acoustics)
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8
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- The mouth simulator was built inside a ellipsoidal dummy head, employing
low-cost parts. Its compliance with the ITU recommendation was confirmed
by means of anechoic directivity tests.
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9
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- In both cases, the anechoic directivity measurements were performed
employing a rotating table, directly synchronized with the sound board
employed for measuring the impulse response. The Aurora software
generates the required pulses on the right channel, which cause the
rotating board to advance.
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10
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- The simmetry revealed to be quite good, and the listening test of the
sequence of impulse responses gives the impression of a pulsive source
rotating around.
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11
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12
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13
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14
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- The binaural microphone exhibit the typical response of a dummy head,
with significant boost around 4-5 kHz.
- The mouth simulator is flat between 200 and 1000 Hz, and requires
substantial equalization outside this interval
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15
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- The spectrum of the emitted test signal should correspond to the
prescriptions of ITU T-P50 Recommendation.
- The overall SPL should be 67 dB(A) at 1m, on axis, for STI standard
measurements
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16
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- The MLS signal is prefiltered, so that the frequency response, measured
at 1m in front of the mouth, complies with the IEC spectrum.
- The filtering is performed by means of the grahic equalizer incorporated
in Cool Edit Pro.
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17
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- The measured IR is saved as a TIM file, and processed with MLSSA
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18
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- The measured IR is saved as a TIM file, and processed with MLSSA
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19
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- The values of m(F) obtained by the measurement without noise were
corrected for the S/N ratio, and compared with the m(F) values measured
with noise
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20
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- The same car was measured at different speeds, employing two different
software tools (DIRAC and MLSSA), and, with the latter, also with
artificial noise compensation applied to the noise-free measurement.
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21
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- The measurements derived by artificial background noise correction of
noise-free impulse responses revealed to provide, on average, slightly
higher values of STI and much lower standard deviation of the results.
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22
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- The hardware and software developed allows for quick and reliable
measurement of STI in cars.
- The background noise can be present during the actual measurement:
however, it is possible to add its effect later, in two different ways:
- Mixing a noise recording over the re-recorded MLS signal, prior of IR
deconvolution (yet to be assessed)
- Correcting the MTF values with the theoretical relationship, knowing
the levels of the signal and of the noise (ideal method when only the
noise spectral values are known, and no recording is available)
- The methodology developed, however, allows also for the creation of
sound samples, containing speech (convolved with the noiseless IR) and
background noise: these sound samples can be employed for listening
tests.
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Notes
