Effect of Signal Quantization on Performance Measures of a 1st Order One Dimensional Differential Microphone Array

In practical systems, recorded analog signals must be digitized for processing, introducing quantization as a critical aspect of data acquisition. While prior studies have examined quantization effects in various signal processing contexts, its impact on differential microphone arrays (DMAs), particularly in one-dimensional (1D) first-order configurations, remains unexplored. This paper investigates the influence of signal quantization on performance of first-order 1D DMAs across various beampatterns. An analytical expression for quantized beamformed output for a first-order 1D DMA has been formulated. The effect of signal quantization has been studied on array performance measures such as the Beampattern, Directivity Factor (DF), Front-to-Back Ratio (FBR), and null depth (ND). Simulation results reveal that beampattern shape remains structurally invariant across quantization bit depths, with quantization primarily affecting ND. DF and FBR remain constant with the varying number of quantization bits. Additionally, ND is shown to be frequency-independent; however, it increases with increasing quantization bit depths, enhancing interference suppression. The study also examines the effect of steering nulls across the azimuthal range, showing that ND degrades as the null moves closer to the source look direction, indicating reduced interference suppression.