Title :
Maximum directivity beamformer for spherical-aperture microphones
Author :
Agmon, Morag ; Rafaely, Boaz ; Tabrikian, Joseph
Author_Institution :
Dept. of Electr. & Comput. Eng., Ben-Gurion Univ. of the Negev, Beer-Sheva, Israel
Abstract :
Spherical microphone arrays have been recently studied for sound analysis and beamforming. These arrays have the advantage of spherical symmetry facilitating three-dimensional analysis. Performance of microphone arrays at the high-frequency range is typically limited by aliasing, which is a result of the spatial sampling process. A potential approach to avoid spatial aliasing is by using continuous sensors, in which spatial sampling is not required. This paper presents an optimal beamforming technique for the spherical-aperture microphone, which is based on a continuous sensor. The proposed beamforming technique is used to compute the optimal real-valued aperture weighting function. Real-valued aperture weighting functions are required to ensure the realizability of the sensor.
Keywords :
array signal processing; microphone arrays; sensors; continuous sensors; maximum directivity beamformer; microphone arrays; optimal beamforming technique; optimal real-valued aperture weighting function; spatial sampling process; spherical symmetry; spherical-aperture microphones; Apertures; Array signal processing; Electromechanical sensors; Fourier transforms; Geometry; Microphone arrays; Planar arrays; Radar antennas; Sampling methods; Structural beams; Aperture Weighting; Beamforming; Spatial Aliasing; Spherical-Aperture Microphone;
Conference_Titel :
Applications of Signal Processing to Audio and Acoustics, 2009. WASPAA '09. IEEE Workshop on
Conference_Location :
New Paltz, NY
Print_ISBN :
978-1-4244-3678-1
Electronic_ISBN :
1931-1168
DOI :
10.1109/ASPAA.2009.5346470
