2000
DOI: 10.1121/1.428813
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Glottal pressure profiles for a diameter of 0.04 cm

Abstract: Computer models of phonation often rely on aerodynamic equations for flow through the glottis. Usually the aerodynamic equations have come from empirical work with steady-flow models made from hard material. The equations simplify the pressure-flow-geometry relations through the larynx. The model used here (model M5) has 14 pressure taps on the vocal folds to give rather complete pressure profiles. Pressure profiles will be reported for symmetric glottal shapes, a minimal diameter of 0.04 cm, and nine glottal … Show more

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“…Several previous studies have motivated the use of the chosen glottal geometry in this study [3][4][5][6]1) , but they have not examined in detail the flow distributions for a wide range of glottal shapes in a more three-dimensional model. The purpose of this study was to quantify the pressure and velocity distributions in a physical glottal model when the glottis takes on different convergent, uniform, and divergent shapes, to better understand the aerodynamics of phonation.…”
mentioning
confidence: 99%
“…Several previous studies have motivated the use of the chosen glottal geometry in this study [3][4][5][6]1) , but they have not examined in detail the flow distributions for a wide range of glottal shapes in a more three-dimensional model. The purpose of this study was to quantify the pressure and velocity distributions in a physical glottal model when the glottis takes on different convergent, uniform, and divergent shapes, to better understand the aerodynamics of phonation.…”
mentioning
confidence: 99%