In the paper a mathematical model of airflow in human vocal folds is presented. The geometry of the glottal channel is based on measurements of excised human larynges. The airflow is modeled by nonstationary incompressible Navier-Stokes equations in a 2D computational domain, which is deformed in time due to vocal fold vibration. The paper presents numerical results and focuses on flow separation in glottis. Quantitative data from numerical simulations are compared to results of measurements by Particle Image Velocimetry (PIV), performed on a scaled self-oscillating physical model of vocal folds
Physical modeling of phonation intends to explain and reproduce the phenomena occurring during the v...
The work introduces implementation of numerical techniques: the ALE (Arbitrary Lagrangian-Eulerian) ...
International audienceThe biomechanical parameters of the multiple tissue layer structure of the voc...
International audienceIn the paper a mathematical model of airflow in human vocal folds is presented...
In the paper a mathematical model of airflow in human vocal folds is presented. The geometry of the ...
The airflow velocities and pressures are calculated from a three-dimensional model of the human lary...
Finite-element modeling of self-sustained vocal fold oscillations during voice production has mostly...
the pressure and velocity fields in coronal plane along the vibrating vocal folds were studied using...
Master thesis deals with creating numerical model of the human vocal folds. Calculation algorithm in...
A two-dimensional (2D) finite element (FE) model of the fluid-structure-acoustic interaction during ...
A new numerical model of the vocal folds is presented based on the well-known two-mass models of the...
A new numerical model of the vocal folds is presented based on the well-known two-mass models of the...
Most flow models used in numerical simulation of voiced sound production rely, for the sake of simpl...
This Master´s thesis deals with use of finite element method for modeling motion and stress of vocal...
Spatial air pressures generated in human vocal tract by vibrating vocal folds present sound sources ...
Physical modeling of phonation intends to explain and reproduce the phenomena occurring during the v...
The work introduces implementation of numerical techniques: the ALE (Arbitrary Lagrangian-Eulerian) ...
International audienceThe biomechanical parameters of the multiple tissue layer structure of the voc...
International audienceIn the paper a mathematical model of airflow in human vocal folds is presented...
In the paper a mathematical model of airflow in human vocal folds is presented. The geometry of the ...
The airflow velocities and pressures are calculated from a three-dimensional model of the human lary...
Finite-element modeling of self-sustained vocal fold oscillations during voice production has mostly...
the pressure and velocity fields in coronal plane along the vibrating vocal folds were studied using...
Master thesis deals with creating numerical model of the human vocal folds. Calculation algorithm in...
A two-dimensional (2D) finite element (FE) model of the fluid-structure-acoustic interaction during ...
A new numerical model of the vocal folds is presented based on the well-known two-mass models of the...
A new numerical model of the vocal folds is presented based on the well-known two-mass models of the...
Most flow models used in numerical simulation of voiced sound production rely, for the sake of simpl...
This Master´s thesis deals with use of finite element method for modeling motion and stress of vocal...
Spatial air pressures generated in human vocal tract by vibrating vocal folds present sound sources ...
Physical modeling of phonation intends to explain and reproduce the phenomena occurring during the v...
The work introduces implementation of numerical techniques: the ALE (Arbitrary Lagrangian-Eulerian) ...
International audienceThe biomechanical parameters of the multiple tissue layer structure of the voc...