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Literature DB >> 21218861

On the acoustical relevance of supraglottal flow structures to low-frequency voice production.

Abstract

The supraglottal flow exhibits many complex phenomena such as recirculation, jet instabilities, jet attachment to one vocal fold wall, jet flapping, and transition to turbulence. The acoustical relevance of these flow structures to low-frequency voice production was evaluated by disturbing the supraglottal flow field using a cylinder and observing the consequence on the resulting sound pressure field. Despite a significantly altered supraglottal flow field due to the presence of the cylinder, only small changes in sound pressure amplitude and spectral shape were observed. The implications of the results on our understanding of phonation physics and modeling of phonation are discussed.

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Year: 2010 PMID： 21218861 PMCID： PMC3013154 DOI： 10.1121/1.3515838

Source DB: PubMed Journal: J Acoust Soc Am ISSN： 0001-4966 Impact factor: 1.840

14 in total

1. Experimental verification of the quasi-steady approximation for aerodynamic sound generation by pulsating jets in tubes.

Authors: Zhaoyan Zhang; Luc Mongeau; Steven H Frankel
Journal: J Acoust Soc Am Date: 2002-10 Impact factor: 1.840

2. Flow visualization and pressure distributions in a model of the glottis with a symmetric and oblique divergent angle of 10 degrees.

Authors: Daoud Shinwari; Ronald C Scherer; Kenneth J DeWitt; Abdollah A Afjeh
Journal: J Acoust Soc Am Date: 2003-01 Impact factor: 1.840

On the acoustical relevance of supraglottal flow structures to low-frequency voice production.

1. Experimental verification of the quasi-steady approximation for aerodynamic sound generation by pulsating jets in tubes.

2. Flow visualization and pressure distributions in a model of the glottis with a symmetric and oblique divergent angle of 10 degrees.

3. The influence of subglottal acoustics on laboratory models of phonation.

4. An in vitro setup to test the relevance and the accuracy of low-order vocal folds models.

5. Low-dimensional models of the glottal flow incorporating viscous-inviscid interaction.

6. Three-dimensional nature of the glottal jet.

7. Analysis of flow-structure interaction in the larynx during phonation using an immersed-boundary method.

8. Analysis, synthesis, and perception of voice quality variations among female and male talkers.

9. Aerodynamically and acoustically driven modes of vibration in a physical model of the vocal folds.

10. Influence of vocal fold stiffness and acoustic loading on flow-induced vibration of a single-layer vocal fold model.

1. Mechanics of human voice production and control.

2. Experimental validation of a three-dimensional reduced-order continuum model of phonation.

3. TOWARD REAL-TIME PHYSICALLY-BASED VOICE SIMULATION: AN EIGENMODE-BASED APPROACH.

4. Quantification of the Intraglottal Pressure Induced by Flow Separation Vortices Using Large Eddy Simulation.

5. Impact of the Paraglottic Space on Voice Production in an MRI-Based Vocal Fold Model.