Acoustic beamforming array design methods over irregular shaped areas
Acoustic beamforming array design methods over irregular shaped areas
Acoustic beamforming array design methods are typically suited for circular and rectangular areas. A comparison of three array design methods is presented in this paper over irregular shaped areas, including L-shapes and arches. Partial-logarithmic spiral arrays that possess their geometric center either at the origin of the array area or the centroid of the irregular shaped area are compared against randomized array designs based on maximum sidelobe level (MSL) parameters and arrays generated using a recently published array design method named the adaptive array reduction method (AARM). In the AARM, a large array is reduced to a smaller array by seeking the removed microphone that possesses the minimum value of the MSL, the main lobe width (MLW), and a lobe distortion term. The AARM is also tested in two practical cases against a partial spiral array design used at the NASA Langley low-turbulence pressure tunnel and a hypothetical rectangular wall case. In both cases, the AARM showed superior performance to the logarithmic spiral arrays in all cases based on MSL and MLW criteria. Of the three methods compared, the AARM best utilizes the full potential array aperture of an irregular area and therefore produces the best MSL, MLW, and lobe distortion values.
Arcondoulis, E.J.G.
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Liu, Y.
305ae3ac-3b65-4c3e-a8ac-ec0f5e30761a
1 June 2021
Arcondoulis, E.J.G.
4e0c8bdf-1810-4d4e-b8e8-9ba9ccd6b746
Liu, Y.
305ae3ac-3b65-4c3e-a8ac-ec0f5e30761a
Arcondoulis, E.J.G. and Liu, Y.
(2021)
Acoustic beamforming array design methods over irregular shaped areas.
Journal of Vibration and Acoustics, Transactions of the ASME, 143 (3).
(doi:10.1115/1.4049943).
Abstract
Acoustic beamforming array design methods are typically suited for circular and rectangular areas. A comparison of three array design methods is presented in this paper over irregular shaped areas, including L-shapes and arches. Partial-logarithmic spiral arrays that possess their geometric center either at the origin of the array area or the centroid of the irregular shaped area are compared against randomized array designs based on maximum sidelobe level (MSL) parameters and arrays generated using a recently published array design method named the adaptive array reduction method (AARM). In the AARM, a large array is reduced to a smaller array by seeking the removed microphone that possesses the minimum value of the MSL, the main lobe width (MLW), and a lobe distortion term. The AARM is also tested in two practical cases against a partial spiral array design used at the NASA Langley low-turbulence pressure tunnel and a hypothetical rectangular wall case. In both cases, the AARM showed superior performance to the logarithmic spiral arrays in all cases based on MSL and MLW criteria. Of the three methods compared, the AARM best utilizes the full potential array aperture of an irregular area and therefore produces the best MSL, MLW, and lobe distortion values.
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Published date: 1 June 2021
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Local EPrints ID: 505923
URI: http://eprints.soton.ac.uk/id/eprint/505923
ISSN: 1048-9002
PURE UUID: c98a5762-f6db-471d-9553-bffa147121de
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Date deposited: 23 Oct 2025 16:56
Last modified: 24 Oct 2025 02:15
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Author:
E.J.G. Arcondoulis
Author:
Y. Liu
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