Amplitude, phase, location, and orientation calibration of an acoustic vector sensor array, Part I: Theory

An acoustic vector sensor array consists of multiple sound pressure microphones and particle velocity sensors. A pressure microphone usually has an omni-directional response, yet a particle velocity sensor is directional. Currently, acoustic vector sensor arrays are under investigation for far field...

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Veröffentlicht in:	The Journal of the Acoustical Society of America 2010-03, Vol.127 (3_Supplement), p.1857-1857
1. Verfasser:	de Bree, Hans-Elias
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Sprache:	eng
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description	An acoustic vector sensor array consists of multiple sound pressure microphones and particle velocity sensors. A pressure microphone usually has an omni-directional response, yet a particle velocity sensor is directional. Currently, acoustic vector sensor arrays are under investigation for far field source localization and visualization. One of the major practical issues in these applications, however, is to determine the accurate position, orientation, and complex (phase and amplitude) sensitivity of each sensor within the array. In this study, a calibration method is developed to determine each of those crucial parameters based on a limited number of measurements with a reference sensor and multiple sound sources located at known locations. The calibration method is also designed to be robust to mistakenly switched cable connections. Ideally, the calibration process should take place in an anechoic environment, but efforts have been made to compensate the effects of moderate background noise and reflections.
doi_str_mv	10.1121/1.3384407
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title	Amplitude, phase, location, and orientation calibration of an acoustic vector sensor array, Part I: Theory
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