Wave-based active control for nonreciprocal acoustics using a planar array of secondary sources
Wave-based active control for nonreciprocal acoustics using a planar array of secondary sources
There has been significant interest in the design of nonreciprocal acoustic devices that allow acoustic waves to be perfectly transmitted in one direction, whilst the acoustic waves propagating in the opposite direction are blocked or reflected. Previously proposed nonreciprocal acoustic devices have broken the symmetry of transmission by introducing nonlinearities or resonant cavities. However, these nonreciprocal acoustic devices typically have limitations, such as signal distortions and the bandwidth over which nonreciprocal behaviour can be achieved is narrow. This paper will investigate how active control can be used to minimise the transmitted and reflected waves independently to achieve nonreciprocal sound transmission and absorption using a planar array of secondary sources in a two-dimensional environment. The advantage of the proposed active control system is that it is fully adaptable, which means that the directivity of nonreciprocal behaviour can also be reversed. The performance of the proposed wave-based active control system is investigated for a range of angles of incidence and its performance limitations are explored.
Active noise control, Nonreciprocal transmission
Tan, Joe
b740c9b2-e880-4e20-92ba-febaa7f688a1
Cheer, Jordan
8e452f50-4c7d-4d4e-913a-34015e99b9dc
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
5 August 2021
Tan, Joe
b740c9b2-e880-4e20-92ba-febaa7f688a1
Cheer, Jordan
8e452f50-4c7d-4d4e-913a-34015e99b9dc
Daley, Stephen
53cef7f1-77fa-4a4c-9745-b6a0ba4f42e6
Tan, Joe, Cheer, Jordan and Daley, Stephen
(2021)
Wave-based active control for nonreciprocal acoustics using a planar array of secondary sources.
Internoise 2021, , Washington, D.C., United States.
01 - 05 Aug 2021.
(doi:10.3397/IN-2021-3110).
Record type:
Conference or Workshop Item
(Paper)
Abstract
There has been significant interest in the design of nonreciprocal acoustic devices that allow acoustic waves to be perfectly transmitted in one direction, whilst the acoustic waves propagating in the opposite direction are blocked or reflected. Previously proposed nonreciprocal acoustic devices have broken the symmetry of transmission by introducing nonlinearities or resonant cavities. However, these nonreciprocal acoustic devices typically have limitations, such as signal distortions and the bandwidth over which nonreciprocal behaviour can be achieved is narrow. This paper will investigate how active control can be used to minimise the transmitted and reflected waves independently to achieve nonreciprocal sound transmission and absorption using a planar array of secondary sources in a two-dimensional environment. The advantage of the proposed active control system is that it is fully adaptable, which means that the directivity of nonreciprocal behaviour can also be reversed. The performance of the proposed wave-based active control system is investigated for a range of angles of incidence and its performance limitations are explored.
Text
Internoise_2021_conference_paper_final
More information
Published date: 5 August 2021
Additional Information:
Funding Information:
This research was partially supported by an EPRSC iCASE studentship (Voucher number: 17000146) and the Intelligent Structures for Low Noise Environments (ISLNE) EPSRC Prosperity Partnership (EP/S03661X/1).
Publisher Copyright:
© INTER-NOISE 2021 .All right reserved.
Venue - Dates:
Internoise 2021, , Washington, D.C., United States, 2021-08-01 - 2021-08-05
Keywords:
Active noise control, Nonreciprocal transmission
Identifiers
Local EPrints ID: 450758
URI: http://eprints.soton.ac.uk/id/eprint/450758
PURE UUID: 6c68fb62-d8b6-4144-bb3d-4002eeb0f785
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Date deposited: 10 Aug 2021 16:31
Last modified: 17 Mar 2024 03:23
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