A Avni, J Ahrens, M Geier, S Spors, H Wierstorf, B Rafaely, "Spatial perception of sound fields recorded by spherical microphone arrays with varying spatial resolution," The Journal of the Acoustical Society of America 133, p. 2711-2721 (2013). [ link ]
Bibtex
@article{Avni2013,
title = {Spatial perception of sound fields recorded by spherical
microphone arrays with varying spatial resolution},
author = {Avni, Amir and Ahrens, Jens and Geier, Matthias and Spors, Sascha
and Wierstorf, Hagen and Rafaely, Boaz},
journal = {The Journal of the Acoustical Society of America},
year = {2013},
volume = {133},
number = {5},
pages = {2711--2721},
doi = {10.1121/1.4795780}
url = {https://doi.org/10.1121/1.4795780}
}
Abstract
The area of sound field synthesis has significantly advanced in the past decade, facilitated by the development of high-quality sound-field capturing and re-synthesis systems. Spherical microphone arrays are among the most recently developed systems for sound field capturing, enabling processing and analysis of three-dimensional sound fields in the spherical harmonics domain. In spite of these developments, a clear relation between sound fields recorded by spherical microphone arrays and their perception with a re-synthesis system has not yet been established, although some relation to scalar measures of spatial perception was recently presented. This paper presents an experimental study of spatial sound perception with the use of a spherical microphone array for sound recording and headphone-based binaural sound synthesis. Sound field analysis and processing is performed in the spherical harmonics domain with the use of head-related transfer functions and simulated enclosed sound fields. The effect of several factors, such as spherical harmonics order, frequency bandwidth, and spatial sampling, are investigated by applying the repertory grid technique to the results of the experiment, forming a clearer relation between sound-field capture with a spherical microphone array and its perception using binaural synthesis regarding space, frequency, and additional artifacts. The experimental study clearly shows that a source will be perceived more spatially sharp and more externalized when represented by a binaural stimuli reconstructed with a higher spherical harmonics order. This effect is apparent from low spherical harmonics orders. Spatial aliasing, as a result of sound field capturing with a finite number of microphones, introduces unpleasant artifacts which increased with the degree of aliasing error.