Achievable maximum-directivity beamforming for spherical microphone arrays with random array errors

Haohai Sun; Shefeng Yan; U. Peter Svensson; Audun Solvang; Johan L. Nielsen

Achievable maximum-directivity beamforming for spherical microphone arrays with random array errors

Haohai Sun^*, Shefeng Yan, U. Peter Svensson, Audun Solvang, Johan L. Nielsen

^*Corresponding author for this work

Research output: Contribution to journal › Conference article › peer-review

2 Citations (Scopus)

Abstract

The maximum-directivity beamformers, or the so-called plane wave decomposition (PWD) beamformers have been widely studied and used for spherical microphone arrays, but they are known to be sensitive to random array errors that exist in practical applications. In this paper, a robust maximum-directivity beamforming approach based on the spherical harmonics framework and worst-case performance optimization techniques is proposed. The approach is developed for both the space domain and the spherical harmonics domain. Given the known maximum level of array errors, it can automatically find and yield the achievable maximumdirectivity for spherical microphone array beamformers, and does not require manual tuning of robustness parameters, which is the major advantage over the white noise gain constrained robustness control approaches that have been developed earlier for spherical microphone arrays.

Original language	English
Pages (from-to)	1929-1933
Number of pages	5
Journal	European Signal Processing Conference
Publication status	Published - 2010
Externally published	Yes
Event	18th European Signal Processing Conference, EUSIPCO 2010 - Aalborg, Denmark Duration: 23 Aug 2010 → 27 Aug 2010

Cite this

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title = "Achievable maximum-directivity beamforming for spherical microphone arrays with random array errors",

abstract = "The maximum-directivity beamformers, or the so-called plane wave decomposition (PWD) beamformers have been widely studied and used for spherical microphone arrays, but they are known to be sensitive to random array errors that exist in practical applications. In this paper, a robust maximum-directivity beamforming approach based on the spherical harmonics framework and worst-case performance optimization techniques is proposed. The approach is developed for both the space domain and the spherical harmonics domain. Given the known maximum level of array errors, it can automatically find and yield the achievable maximumdirectivity for spherical microphone array beamformers, and does not require manual tuning of robustness parameters, which is the major advantage over the white noise gain constrained robustness control approaches that have been developed earlier for spherical microphone arrays.",

author = "Haohai Sun and Shefeng Yan and {Peter Svensson}, U. and Audun Solvang and Nielsen, {Johan L.}",

year = "2010",

language = "English",

pages = "1929--1933",

journal = "European Signal Processing Conference",

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publisher = "European Signal Processing Conference, EUSIPCO",

note = "18th European Signal Processing Conference, EUSIPCO 2010 ; Conference date: 23-08-2010 Through 27-08-2010",

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TY - JOUR

T1 - Achievable maximum-directivity beamforming for spherical microphone arrays with random array errors

AU - Sun, Haohai

AU - Yan, Shefeng

AU - Peter Svensson, U.

AU - Solvang, Audun

AU - Nielsen, Johan L.

PY - 2010

Y1 - 2010

N2 - The maximum-directivity beamformers, or the so-called plane wave decomposition (PWD) beamformers have been widely studied and used for spherical microphone arrays, but they are known to be sensitive to random array errors that exist in practical applications. In this paper, a robust maximum-directivity beamforming approach based on the spherical harmonics framework and worst-case performance optimization techniques is proposed. The approach is developed for both the space domain and the spherical harmonics domain. Given the known maximum level of array errors, it can automatically find and yield the achievable maximumdirectivity for spherical microphone array beamformers, and does not require manual tuning of robustness parameters, which is the major advantage over the white noise gain constrained robustness control approaches that have been developed earlier for spherical microphone arrays.

AB - The maximum-directivity beamformers, or the so-called plane wave decomposition (PWD) beamformers have been widely studied and used for spherical microphone arrays, but they are known to be sensitive to random array errors that exist in practical applications. In this paper, a robust maximum-directivity beamforming approach based on the spherical harmonics framework and worst-case performance optimization techniques is proposed. The approach is developed for both the space domain and the spherical harmonics domain. Given the known maximum level of array errors, it can automatically find and yield the achievable maximumdirectivity for spherical microphone array beamformers, and does not require manual tuning of robustness parameters, which is the major advantage over the white noise gain constrained robustness control approaches that have been developed earlier for spherical microphone arrays.

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M3 - Conference article

AN - SCOPUS:84863787225

SN - 2219-5491

SP - 1929

EP - 1933

JO - European Signal Processing Conference

JF - European Signal Processing Conference

T2 - 18th European Signal Processing Conference, EUSIPCO 2010

Y2 - 23 August 2010 through 27 August 2010

ER -

Achievable maximum-directivity beamforming for spherical microphone arrays with random array errors

Abstract

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