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dc.contributor.authorGuasch Fortuny, Oriol
dc.contributor.authorArnela, Marc
dc.contributor.authorCodina, Ramon
dc.contributor.authorEspinoza Román, Héctor Gabriel
dc.contributor.otherUniversitat Politècnica de Catalunya. Departament de Resistència de Materials i Estructures a l'Enginyeria
dc.date.accessioned2015-09-03T16:35:10Z
dc.date.issued2015
dc.identifier.citationGuasch, O., Arnela, M., Codina, R., Espinoza, H. Stabilized finite element formulation for the mixed convected wave equation in domains with driven flexible boundaries. A: Noise and Vibration: Emerging Technologies. "NOVEM 2015: Noise and vibration: emerging technologies". Dubrobnik: 2015, p. 48437-1-48437-13.
dc.identifier.urihttp://hdl.handle.net/2117/76608
dc.description.abstractA stabilized finite element (FEM) formulation for the wave equation in mixed form with convection is presented, which permits using the same interpolation fields for the acoustic pressure and the acoustic particle velocity. The formulation is based on a variational multiscale approach, in which the problem unknowns are split into a large scale component that can be captured by the computational mesh, and a small, subgrid scale component, whose influence into the large scales has to be modelled. A suitable option is that of taking the subgrid scales, or subscales, as being related to the finite element residual by means of a matrix of stabilization parameters. The design of the later turns to be the key for the good performance of the method. In addition, the mixed convected wave equation has been set in an arbitrary Lagrangian-Eulerian (ALE) frame of reference to account for domains with moving boundaries. The movement of the boundaries in the present work consists of two components, an external prescribed motion and a motion related to the boundary elastic back reaction to the acoustic pressure, in the normal direction. A mass-damper-stiffness auxiliary equation is solved for each boundary node to include this effect. As a first benchmark example, we have considered the case of 2D simple duct acoustics with mean flow. More complex 3D examples are also presented consisting of vowel and diphthong generation, following a numerical approach to voice production. The numerical simulation of voice not only allows one to see how waves propagate inside the vocal tract, but also to collect the acoustic pressure at a node close to the mouth exit, convert it to an audio file and listen to it.
dc.language.isoeng
dc.subjectÀrees temàtiques de la UPC::Física::Física de fluids::Flux de fluids
dc.subject.lcshWaves--Mathematical models
dc.titleStabilized finite element formulation for the mixed convected wave equation in domains with driven flexible boundaries
dc.typeConference report
dc.subject.lemacOnades -- Models matemàtics
dc.contributor.groupUniversitat Politècnica de Catalunya. ANiComp - Anàlisi numèrica i computació científica
dc.rights.accessRestricted access - publisher's policy
drac.iddocument15340621
dc.description.versionPostprint (published version)
dc.date.lift10000-01-01
upcommons.citation.authorGuasch, O., Arnela, M., Codina, R., Espinoza, H.
upcommons.citation.contributorNoise and Vibration: Emerging Technologies
upcommons.citation.pubplaceDubrobnik
upcommons.citation.publishedtrue
upcommons.citation.publicationNameNOVEM 2015: Noise and vibration: emerging technologies
upcommons.citation.startingPage48437-1
upcommons.citation.endingPage48437-13


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