TY - JOUR
T1 - Construction of an omnidirectional parametric loudspeaker consisting in a spherical distribution of ultrasound transducers
AU - Arnela, Marc
AU - Guasch, Oriol
AU - Sánchez-Martín, Patricia
AU - Camps, Joan
AU - Alsina-Pagès, Rosa Ma
AU - Martínez-Suquía, Carme
N1 - Funding Information:
This work has been supported by the BUILT2SPEC project, which has received funding from the European Union’s Horizon 2020 Research and Innovation Program under Grant No. 637221. Acknowledgment is also given to the Universitat Ramon Llull internal project 2017-URL-Proj-015.
Publisher Copyright:
© 2018 by the authors. Licensee MDPI, Basel, Switzerland.
PY - 2018/12
Y1 - 2018/12
N2 - Omnidirectional sound sources are needed to perform a large variety of tests in acoustics. Typically, they consist of conventional speaker drivers arranged in a dodecahedron. However, the directivity of the speaker drivers sharpens with frequency, which induces an intense decrease of the sound pressure levels at the edges of the dodechaedron. In this work, the problem is mitigated by building an Omnidirectional Parametric Loudspeaker (OPL), which contains hundreds of small ultrasound transducers set on a sphere. Each transducer emits an ultrasonic carrier wave modulated by an audible signal. Thanks to nonlinear propagation, the air itself demodulates the signal bringing it back to the audible range. The construction of an OPL prototype is challenging. The structure has been built by 3D-printing a set of pieces that conform to the sphere. Each piece contains the exact location of the transducers, which are aligned in parallels to facilitate the structural assembly and the wiring. The performance of the OPL has been tested in an anechoic chamber. Measurements show that the OPL has a good omnidirectional behavior for most frequencies. It clearly improves the directivity of dodechaedral sources in the high frequency range, but performs worse at low frequencies.
AB - Omnidirectional sound sources are needed to perform a large variety of tests in acoustics. Typically, they consist of conventional speaker drivers arranged in a dodecahedron. However, the directivity of the speaker drivers sharpens with frequency, which induces an intense decrease of the sound pressure levels at the edges of the dodechaedron. In this work, the problem is mitigated by building an Omnidirectional Parametric Loudspeaker (OPL), which contains hundreds of small ultrasound transducers set on a sphere. Each transducer emits an ultrasonic carrier wave modulated by an audible signal. Thanks to nonlinear propagation, the air itself demodulates the signal bringing it back to the audible range. The construction of an OPL prototype is challenging. The structure has been built by 3D-printing a set of pieces that conform to the sphere. Each piece contains the exact location of the transducers, which are aligned in parallels to facilitate the structural assembly and the wiring. The performance of the OPL has been tested in an anechoic chamber. Measurements show that the OPL has a good omnidirectional behavior for most frequencies. It clearly improves the directivity of dodechaedral sources in the high frequency range, but performs worse at low frequencies.
KW - Nonlinear acoustics
KW - Omnidirectional parametric loudspeaker
KW - Omnidirectional sound source
KW - Parametric acoustic array
KW - Ultrasound transducer
UR - http://www.scopus.com/inward/record.url?scp=85058395910&partnerID=8YFLogxK
U2 - 10.3390/s18124317
DO - 10.3390/s18124317
M3 - Article
C2 - 30544537
AN - SCOPUS:85058395910
SN - 1424-8220
VL - 18
JO - Sensors (Switzerland)
JF - Sensors (Switzerland)
IS - 12
M1 - 4317
ER -