Dear subscribers of the colloquium newsletter,
we are happy to inform you about the next date of our Communication
Technology Colloquium.
*Friday, August 23, 2024*
*Speaker*: José Luis Conesa Pérez
*Time:* 10.00 AM
*Location*: hybrid - Lecture room 4G and
https://rwth.zoom.us/j/61215027648?pwd=MTJvayt5bkdka04raWZVempPZGE0Zz09
Meeting-ID: 612 1502 7648
Passwort: 380386
*Master-Lecture: **
**Characterization of Vibration Transfer Paths for Earphones
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Devices that seal the ear canal from the outside, such as insert
earphones, create what is usually referred to as the Occlusion Effect.
This effect generates a coloration of the signals, other than the ones
produced by the device, that reach the eardrum. The consequences of this
coloration are a reduction of the higher components of the spectrum of
air-borne sounds, and an amplification of low-frequency sounds that
reach the ear canal through bone vibration. In the efforts to cancel the
Occlusion Effect, there is new research into adding vibration sensors to
the earphones. These sensors can record the body-conducted sounds to
counter the coloration introduced on the voice by the Occlusion Effect
and enhance speech.
Due to the closeness of the vibration sensor to the earphone, the
Feedback Path has to be characterized in order to ensure stability of
the system and avoid possible echoes. Therefore, this project’s
objective is to study the feedback of the system. To this aim, a series
of experiments have been conducted to test how the feedback from the
loudspeaker is affected by different variables such as the tightness of
the fit (how well the earphone seals the ear canal), the silicone tips
used or changing the mass of the earphone. With these tests some
insights into how the earphones work was gained, such as how the
feedback can be reduced due to the ear canal not being perfectly sealed
or by making the earphone heavier. The reduction caused by both previous
examples is due to the loudspeaker having increased difficulties in
moving the earphone due to energy escaping from the ear canal or a
higher inertia of the earphone. In addition to these experiments, a
measurement of a group of participants was conducted to inspect how the
Feedback Path varies between individuals. To finalize the project, the
basic mechanical behavior of the earphone when it reproduces inside of
the ear canal was analyzed with the aim of creating a basic lumped
element model that roughly describes its movements. This model proved to
be only good as a first approximation, as it could not represent all the
complexities of the vibration paths due to its simplicity. A system
identification was also performed, with N4SID, on the lower parts of the
spectrum of the Feedback Path to obtain the various poles and zeroes
that represent the filter and observe their placement in the complex plane.
All interested parties are cordially invited, registration is not required.
General information on the colloquium, as well as a current list of
dates of the Communication Technology Colloquium can be found at:
https://www.iks.rwth-aachen.de/aktuelles/kolloquium
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*Mit freundlichen Grüßen*
*Anett Schindler*
Institute of Communication Systems (IKS)
Prof. Dr. -Ing. Peter Jax
RWTH Aachen University
Muffeter Weg 3a, 52074 Aachen, Germany
+49 241 80 26958
schindler(a)iks.rwth-aachen.de
https://www.iks.rwth-aachen.de/