Cochlea‑inspired design of an acoustic rainbow sensor with a smoothly varying frequency response
Cochlea‑inspired design of an acoustic rainbow sensor with a smoothly varying frequency response
A number of physical arrangements for acoustic rainbow sensors have been suggested, where the aim is to separate different frequency components into different physical locations along the sensor. Although such spatial discrimination has been achieved with several designs of sensor, the resulting frequency responses at a given position along the sensor are generally not smoothly varying. In contrast, the cochlea provides an interesting natural example of a rainbow sensor, which has an exponential frequency distribution and whose response does vary smoothly with frequency. The design of a rainbow sensor is presented that has a number of discrete resonators and an exponential frequency distribution. We discuss the conditions for a smoothly varying frequency response in such a sensor, as part of a broader design strategy. It is shown that the damping within the resonators determines the trade-off between the frequency resolution and the number of elements required to achieve a smooth response. The connection is explained between this design and that of an effective acoustic absorber. The finite number of hair cells means that the cochlea itself can be thought of as being composed of discrete units and the conditions derived above are compared with those that are observed in the cochlea.
Karlos, Angelis
c740900b-67d0-41a0-be44-e270163de37d
Elliott, Stephen
721dc55c-8c3e-4895-b9c4-82f62abd3567
1 December 2020
Karlos, Angelis
c740900b-67d0-41a0-be44-e270163de37d
Elliott, Stephen
721dc55c-8c3e-4895-b9c4-82f62abd3567
Karlos, Angelis and Elliott, Stephen
(2020)
Cochlea‑inspired design of an acoustic rainbow sensor with a smoothly varying frequency response.
Scientific Reports, 10 (1), [10803].
(doi:10.1038/s41598-020-67608-z).
Abstract
A number of physical arrangements for acoustic rainbow sensors have been suggested, where the aim is to separate different frequency components into different physical locations along the sensor. Although such spatial discrimination has been achieved with several designs of sensor, the resulting frequency responses at a given position along the sensor are generally not smoothly varying. In contrast, the cochlea provides an interesting natural example of a rainbow sensor, which has an exponential frequency distribution and whose response does vary smoothly with frequency. The design of a rainbow sensor is presented that has a number of discrete resonators and an exponential frequency distribution. We discuss the conditions for a smoothly varying frequency response in such a sensor, as part of a broader design strategy. It is shown that the damping within the resonators determines the trade-off between the frequency resolution and the number of elements required to achieve a smooth response. The connection is explained between this design and that of an effective acoustic absorber. The finite number of hair cells means that the cochlea itself can be thought of as being composed of discrete units and the conditions derived above are compared with those that are observed in the cochlea.
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Karlos & Elliott Sci Rep 2020 Rainbow sensors
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Accepted/In Press date: 11 June 2020
Published date: 1 December 2020
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© 2020, The Author(s).
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Local EPrints ID: 443530
URI: http://eprints.soton.ac.uk/id/eprint/443530
ISSN: 2045-2322
PURE UUID: 5cba3d5f-87ab-4171-85b9-23f44e7a6b11
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Date deposited: 28 Aug 2020 16:30
Last modified: 16 Mar 2024 09:00
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Author:
Angelis Karlos
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