UPPER LIMITS OF AUDITORY MOTION PERCEPTION WITH PERCUSSION SOUNDS

Authors

  • Cynthia Tarlao <p>School of Information Studies, McGill University</p><p>Centre for Interdisciplinary Research in Music Media and Technology</p>
  • Ilja Frissen <p>School of Information Studies, McGill University</p><p>Centre for Interdisciplinary Research in Music Media and Technology</p>
  • Maélic Louart <p>School of Information Studies, McGill University</p><p>Centre for Interdisciplinary Research in Music Media and Technology</p>
  • Catherine Guastavino <p>School of Information Studies, McGill University</p><p>Centre for Interdisciplinary Research in Music Media and Technology</p>

Abstract

With the emergence of electroacoustic music in the 1950s, composers started composing music with sounds moving around the listeners.  Perceptual studies on sound localization have traditionally focused on static sound sources, but auditory motion perception has garnered increased research attention recently. Research in our lab used synthetic sounds and noises to estimate the upper limit for circular auditory motion perception; that is the velocity above which listeners are no longer able to track sounds that are revolving around them.

 

The current study extends this line of research to more instrumental sounds that are spectrally and temporally more complex than our previous stimuli. Sounds were extracted from a recording of Persephassa (Xenakis, 1969) a percussion piece for six players.  Seated at the center of a 16-speaker circular array, 21 participants with normal hearing were asked to indicate in which direction the sound stimuli revolved around them. We used a two-alternative forced choice 2-up, 1-down adaptive procedure to estimate the upper limit for different instrumental sounds and well as pink noise.  The upper limits varied as a function of the type of instrument, the family of instrument, and the playing technique. Specifically, the upper limits for three simantras (two wood and one metal) and a piccolo snare drum were significantly lower than for pink noise. The upper limits for two metal instruments (simantra and cymbal) were significantly different from each other.

 

To trace the variation in upper limits to acoustic properties, audio descriptors were extracted from the instrumental sounds using the MIR toolbox. Based on this analysis, we generated new stimuli with varying signal-to-noise ratios and event densities. A follow-up experiment investigated the effect of these features on the upper limit.

Additional Files

Published

2017-08-20

How to Cite

1.
Tarlao C, Frissen I, Louart M, Guastavino C. UPPER LIMITS OF AUDITORY MOTION PERCEPTION WITH PERCUSSION SOUNDS. Canadian Acoustics [Internet]. 2017 Aug. 20 [cited 2024 Mar. 28];45(3):140-1. Available from: https://jcaa.caa-aca.ca/index.php/jcaa/article/view/3158

Issue

Section

Proceedings of the Acoustics Week in Canada