On the General Relation of Wave Field Synthesis and Spectral Division Method for Linear Arrays

Sound field synthesis aims at the reproduction of an arbitrary target sound field over an extended listening area applying a densely spaced loudspeaker ensemble. Two basic analytic methodologies-the explicit and the implicit-exist in order to derive the required loudspeaker driving functions. The ex...

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Bibliographic Details
Published in:IEEE/ACM transactions on audio, speech, and language processing speech, and language processing, 2018-12, Vol.26 (12), p.2393-2403
Main Authors: Firtha, Gergely, Fiala, Peter, Schultz, Frank, Spors, Sascha
Format: Article
Language:English
Subjects:
Approximation
Automobile industry
Geometry
Green's function methods
Integral equations
Linear arrays
Mathematical analysis
Receivers
Sound
Sound reproduction
spectral division method
Speech processing
Synthesis
Three-dimensional displays
Two dimensional displays
Wave field synthesis
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Summary:Sound field synthesis aims at the reproduction of an arbitrary target sound field over an extended listening area applying a densely spaced loudspeaker ensemble. Two basic analytic methodologies-the explicit and the implicit-exist in order to derive the required loudspeaker driving functions. The explicit solution aims at the direct solution of the involved integral equation describing the general sound field synthesis problem, resulting in driving functions in the form of a spectral integral. The implicit solution extracts the driving function from an appropriate boundary integral representation of the target sound field. So far the relationship between two approaches was investigated for target field specific synthesis scenarios. For linear arrays this paper introduces a high-frequency approximation for the explicit solution resulting in a novel, purely spatial domain formulation of the direct approach. The presented driving functions allow the synthesis of an arbitrary virtual sound field, optimizing the reproduction on an arbitrary reference line. It is furthermore shown that for an arbitrary virtual sound field, the implicit solution constitutes a high-frequency approximation of the explicit method.
ISSN:2329-9290
2329-9304
DOI:10.1109/TASLP.2018.2865091