Numerical modeling of the human phonatory process has become more and more in focus
during the last two decades. The increase in computational power and the use of high …

This article deals with large-eddy simulations of three-dimensional incompressible laryngeal
flow followed by acoustic simulations of human phonation of five cardinal English vowels,/A …

In an aeroacoustic simulation of human voice production, the effect of the sub-grid scale
(SGS) model on the acoustic spectrum was investigated. In the first step, incompressible …

Acoustic data has long been harvested in fundamental voice investigations since it is easily
obtained using a microphone. However, acoustic signals alone do not reveal much about …

This paper deals with the numerical simulation of the flow induced sound as generated in
the human phonation process. The two-dimensional fluid-structure interaction problem is …

The paper presented a three-dimensional, first-principle based fluid–structure–acoustics
interaction computer model of voice production, which employed a more realistic human …

Human phonation is based on the interaction between tracheal airflow and laryngeal
dynamics. This fluid-structure interaction is based on the energy exchange between airflow …

In a partitioned approach for computational fluid–structure interaction (FSI) the coupling
between fluid and structure causes substantial computational resources. Therefore, a …

Simulation of the phonatory flow-structure interaction has been conducted in a three-
dimensional, tubular shaped laryngeal model that has been designed with a high level of …

Accurate computation of highly unsteady and massively separated airflow in human vocal
folds during phonation, which is fundamental for the understanding and modeling of the …