Design of Differential Microphone Arrays via a 3d Spatial Difference Operator

Differential microphone arrays (DMAs) can measure and respond to the spatial derivatives of the soundfield, which gives them great potential in high-fidelity acoustic signal acquisition and soundfield measurement. Previous studies on three-dimensional (3D) micro- phone arrays are primarily based on the spherical harmonic decom- position of the soundfield, which inherently limits the array topology to spherical configurations. This paper presents a more flexible 3D DMA and beamformer design method according to the principle of finite difference approximations, offering new insights into the mi- crophone design and soundfield measurement. Using Taylor series expansion, we demonstrate how the spatial derivatives of the sound- field can be approximated by finite differences between microphone signals, laying the foundation of 3D DMAs. Owing to these formula- tions, the differential beamforming method via the spatial difference operator (SDO) can also be extended to the 3D case. Simulation results confirm the effectiveness of the proposed approach.