Spatial localization of concurrent multiple sound sources using phase candidate histogram

Huakang Li; Jie Huang; Minyi Guo; Qunfei Zhao

doi:10.20965/jaciii.2011.p1277

Spatial localization of concurrent multiple sound sources using phase candidate histogram

Huakang Li^*, Jie Huang, Minyi Guo, Qunfei Zhao

^*Corresponding author for this work

Shanghai Jiao Tong University

Research output: Contribution to journal › Article › peer-review

Abstract

Mobile robots communicating with people would benefit from being able to detect sound sources to help localize interesting events in real-life settings. We propose using a spherical robot with four microphones to determine the spatial locations of multiple sound sources in ordinary rooms. The arrival temporal disparities from phase difference histograms are used to calculate the time differences. A precedence effect model suppresses the influence of echoes in reverberant environments. To integrate spatial cues of different microphones, we map the correlation between different microphone pairs on a 3D map corresponding to the azimuth and elevation of sound source direction. Results of experiments indicate that our proposed system provides sound source distribution very clearly and precisely, even concurrently in reverberant environments with the Echo Avoidance (EA) model.

Original language	English
Pages (from-to)	1277-1286
Number of pages	10
Journal	Journal of Advanced Computational Intelligence and Intelligent Informatics
Volume	15
Issue number	9
DOIs	https://doi.org/10.20965/jaciii.2011.p1277
Publication status	Published - Nov 2011
Externally published	Yes

Keywords

Acoustic signal processing
Candidate histogram
Direction estimation
Precedence effect
Time-delay estimation

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10.20965/jaciii.2011.p1277

Cite this

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abstract = "Mobile robots communicating with people would benefit from being able to detect sound sources to help localize interesting events in real-life settings. We propose using a spherical robot with four microphones to determine the spatial locations of multiple sound sources in ordinary rooms. The arrival temporal disparities from phase difference histograms are used to calculate the time differences. A precedence effect model suppresses the influence of echoes in reverberant environments. To integrate spatial cues of different microphones, we map the correlation between different microphone pairs on a 3D map corresponding to the azimuth and elevation of sound source direction. Results of experiments indicate that our proposed system provides sound source distribution very clearly and precisely, even concurrently in reverberant environments with the Echo Avoidance (EA) model.",

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author = "Huakang Li and Jie Huang and Minyi Guo and Qunfei Zhao",

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AU - Li, Huakang

AU - Huang, Jie

AU - Guo, Minyi

AU - Zhao, Qunfei

PY - 2011/11

Y1 - 2011/11

N2 - Mobile robots communicating with people would benefit from being able to detect sound sources to help localize interesting events in real-life settings. We propose using a spherical robot with four microphones to determine the spatial locations of multiple sound sources in ordinary rooms. The arrival temporal disparities from phase difference histograms are used to calculate the time differences. A precedence effect model suppresses the influence of echoes in reverberant environments. To integrate spatial cues of different microphones, we map the correlation between different microphone pairs on a 3D map corresponding to the azimuth and elevation of sound source direction. Results of experiments indicate that our proposed system provides sound source distribution very clearly and precisely, even concurrently in reverberant environments with the Echo Avoidance (EA) model.

AB - Mobile robots communicating with people would benefit from being able to detect sound sources to help localize interesting events in real-life settings. We propose using a spherical robot with four microphones to determine the spatial locations of multiple sound sources in ordinary rooms. The arrival temporal disparities from phase difference histograms are used to calculate the time differences. A precedence effect model suppresses the influence of echoes in reverberant environments. To integrate spatial cues of different microphones, we map the correlation between different microphone pairs on a 3D map corresponding to the azimuth and elevation of sound source direction. Results of experiments indicate that our proposed system provides sound source distribution very clearly and precisely, even concurrently in reverberant environments with the Echo Avoidance (EA) model.

KW - Acoustic signal processing

KW - Candidate histogram

KW - Direction estimation

KW - Precedence effect

KW - Time-delay estimation

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DO - 10.20965/jaciii.2011.p1277

M3 - Article

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JO - Journal of Advanced Computational Intelligence and Intelligent Informatics

JF - Journal of Advanced Computational Intelligence and Intelligent Informatics

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Spatial localization of concurrent multiple sound sources using phase candidate histogram

Abstract

Keywords

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