0000000000496286

AUTHOR

Luis A. Mora

showing 2 related works from this author

A port-Hamiltonian Fluid-Structure Interaction Model for the Vocal folds ⁎ ⁎This work was supported by CONICYT-PFCHA/2017-21170472, and AC3E CONICYT-…

2018

Abstract Fluid-structure interaction models are of special interest for studying the energy transfer between the moving fluid and the mechanical structure in contact. The vocal folds are an example of a fluid-structure system, where the mechanical structure is usually modeled as a mass-spring-damper system. In particular, the estimation of the collision forces of the vocal folds is of high interest in the diagnosis of phonotraumatic voice pathologies. In this context, the port-Hamiltonian modeling framework focuses on the energy flux in the model and the interacting forces. In this paper, we develop a port-Hamiltonian fluid-structure interaction model based on the interconnection methodolog…

0209 industrial biotechnologyInterconnectionComputer scienceEnergy transferEnergy fluxInteraction model02 engineering and technologyCollision01 natural sciencessymbols.namesake020901 industrial engineering & automationmedicine.anatomical_structureClassical mechanicsControl and Systems EngineeringVocal folds0103 physical sciencesFluid–structure interactionsymbolsmedicineHamiltonian (quantum mechanics)010301 acousticsIFAC-PapersOnLine
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Energy-based fluid–structure model of the vocal folds

2020

AbstractLumped elements models of vocal folds are relevant research tools that can enhance the understanding of the pathophysiology of many voice disorders. In this paper, we use the port-Hamiltonian framework to obtain an energy-based model for the fluid–structure interactions between the vocal folds and the airflow in the glottis. The vocal fold behavior is represented by a three-mass model and the airflow is described as a fluid with irrotational flow. The proposed approach allows to go beyond the usual quasi-steady one-dimensional flow assumption in lumped mass models. The simulation results show that the proposed energy-based model successfully reproduces the oscillations of the vocal …

0209 industrial biotechnologyControl and OptimizationGlottisComputer scienceApplied MathematicsAirflow02 engineering and technologyMechanicsFold (geology)ArticlesConservative vector field01 natural sciencesCompressible flowPhysics::Fluid Dynamics020901 industrial engineering & automationmedicine.anatomical_structureFlow (mathematics)Control and Systems EngineeringComputer Science::SoundVocal folds0103 physical sciencesmedicine010301 acousticsEnergy (signal processing)
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