Adaptive sound localisation with a silicon cochlea pair

Vincent Yue-Sek Chan; Craig T. Jin; André van Schaik

doi:10.3389/fnins.2010.00196

Adaptive sound localisation with a silicon cochlea pair

Vincent Yue-Sek Chan, Craig T. Jin, André van Schaik

Research output: Contribution to journal › Article

Abstract

A neuromorphic sound localization system is presented. It employs two microphones and a pair of silicon cochleae with address event interface for front-end processing. The system is based the extraction of interaural time difference from a far-field source. At each frequency channel, a soft-winner-takes-all network is used to preserve timing information before it is processed by a simple neural network to estimate auditory activity at all bearing positions. The estimates are then combined across channels to produce the final estimate. The proposed algorithm is adaptive and supports online learning, enabling the system to compensate for circuit mismatch and environmental changes. Its localization capability was tested with white noise and pure tone stimuli, with an average error of around 3Ã‚Â° in the âˆ’45Ã‚Â° to 45Ã‚Â° range.

Original language	English
Number of pages	11
Journal	Frontiers of Neurology and Neuroscience
Volume	4
Issue number	196
DOIs	https://doi.org/10.3389/fnins.2010.00196
Publication status	Published - 2010

Keywords

acoustic localization
cochlea

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10.3389/fnins.2010.00196

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title = "Adaptive sound localisation with a silicon cochlea pair",

abstract = "A neuromorphic sound localization system is presented. It employs two microphones and a pair of silicon cochleae with address event interface for front-end processing. The system is based the extraction of interaural time difference from a far-field source. At each frequency channel, a soft-winner-takes-all network is used to preserve timing information before it is processed by a simple neural network to estimate auditory activity at all bearing positions. The estimates are then combined across channels to produce the final estimate. The proposed algorithm is adaptive and supports online learning, enabling the system to compensate for circuit mismatch and environmental changes. Its localization capability was tested with white noise and pure tone stimuli, with an average error of around 3{\~A}‚{\^A}° in the {\^a}ˆ{\textquoteright}45{\~A}‚{\^A}° to 45{\~A}‚{\^A}° range.",

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AU - Chan, Vincent Yue-Sek

AU - Jin, Craig T.

AU - Schaik, André van

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N2 - A neuromorphic sound localization system is presented. It employs two microphones and a pair of silicon cochleae with address event interface for front-end processing. The system is based the extraction of interaural time difference from a far-field source. At each frequency channel, a soft-winner-takes-all network is used to preserve timing information before it is processed by a simple neural network to estimate auditory activity at all bearing positions. The estimates are then combined across channels to produce the final estimate. The proposed algorithm is adaptive and supports online learning, enabling the system to compensate for circuit mismatch and environmental changes. Its localization capability was tested with white noise and pure tone stimuli, with an average error of around 3Ã‚Â° in the âˆ’45Ã‚Â° to 45Ã‚Â° range.

AB - A neuromorphic sound localization system is presented. It employs two microphones and a pair of silicon cochleae with address event interface for front-end processing. The system is based the extraction of interaural time difference from a far-field source. At each frequency channel, a soft-winner-takes-all network is used to preserve timing information before it is processed by a simple neural network to estimate auditory activity at all bearing positions. The estimates are then combined across channels to produce the final estimate. The proposed algorithm is adaptive and supports online learning, enabling the system to compensate for circuit mismatch and environmental changes. Its localization capability was tested with white noise and pure tone stimuli, with an average error of around 3Ã‚Â° in the âˆ’45Ã‚Â° to 45Ã‚Â° range.

KW - acoustic localization

KW - cochlea

UR - http://handle.uws.edu.au:8081/1959.7/506034

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DO - 10.3389/fnins.2010.00196

M3 - Article

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VL - 4

JO - Frontiers of Neurology and Neuroscience

JF - Frontiers of Neurology and Neuroscience

IS - 196

ER -

Adaptive sound localisation with a silicon cochlea pair

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Keywords

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