VOLANDRI, Gaia ;CARMIGNANI, Constantino ;DI PUCCIO, Francesca ;FORTE, Paola . Finite Element Formulations Applied to Outer Ear Modeling. Strojniški vestnik - Journal of Mechanical Engineering, [S.l.], v. 60, n.5, p. 363-372, june 2018. ISSN 0039-2480. Available at: <https://www.sv-jme.eu/sl/article/finite-element-formulations-applied-to-outer-ear-modeling/>. Date accessed: 20 dec. 2024. doi:http://dx.doi.org/10.5545/sv-jme.2014.1837.
Volandri, G., Carmignani, C., Di Puccio, F., & Forte, P. (2014). Finite Element Formulations Applied to Outer Ear Modeling. Strojniški vestnik - Journal of Mechanical Engineering, 60(5), 363-372. doi:http://dx.doi.org/10.5545/sv-jme.2014.1837
@article{sv-jmesv-jme.2014.1837, author = {Gaia Volandri and Constantino Carmignani and Francesca Di Puccio and Paola Forte}, title = {Finite Element Formulations Applied to Outer Ear Modeling}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {60}, number = {5}, year = {2014}, keywords = {finite element method, auditory canal, simulation, sound transmission}, abstract = {The work described in this paper is part of a broader research activity on the development of a virtual ear. The present study focuses on the tympanic membrane and auditory canal modeling, which are important components in sound transmission. The standard finite element method (FEM) and an alternative method (the generalized FEM), suitable for modeling sound propagation at high frequencies, were applied. Two domains (fluid and structural) for the auditory canal and the tympanic membrane, respectively, were considered in order to evaluate the coupling of the different methods and to apply a fluid-structure interaction formulation. ANSYS® software was used for solving FEM analyses, while GFEM simulations were obtained by implementing the method in Wolfram Mathematica®. Simulation results include modal response, pressure distribution in the auditory canal and displacement distribution in the tympanic membrane. The identified modal frequencies of the auditory canal agree with published data reported in the literature. The validation of such method with standard FEM simulation at increasing mesh density shows that FEM is more suitable for simulations of the human ear in the audible frequency range, although the generalized formulation could be convenient if an ear model including the whole head or the ultrasound frequency range were investigated.}, issn = {0039-2480}, pages = {363-372}, doi = {10.5545/sv-jme.2014.1837}, url = {https://www.sv-jme.eu/sl/article/finite-element-formulations-applied-to-outer-ear-modeling/} }
Volandri, G.,Carmignani, C.,Di Puccio, F.,Forte, P. 2014 June 60. Finite Element Formulations Applied to Outer Ear Modeling. Strojniški vestnik - Journal of Mechanical Engineering. [Online] 60:5
%A Volandri, Gaia %A Carmignani, Constantino %A Di Puccio, Francesca %A Forte, Paola %D 2014 %T Finite Element Formulations Applied to Outer Ear Modeling %B 2014 %9 finite element method, auditory canal, simulation, sound transmission %! Finite Element Formulations Applied to Outer Ear Modeling %K finite element method, auditory canal, simulation, sound transmission %X The work described in this paper is part of a broader research activity on the development of a virtual ear. The present study focuses on the tympanic membrane and auditory canal modeling, which are important components in sound transmission. The standard finite element method (FEM) and an alternative method (the generalized FEM), suitable for modeling sound propagation at high frequencies, were applied. Two domains (fluid and structural) for the auditory canal and the tympanic membrane, respectively, were considered in order to evaluate the coupling of the different methods and to apply a fluid-structure interaction formulation. ANSYS® software was used for solving FEM analyses, while GFEM simulations were obtained by implementing the method in Wolfram Mathematica®. Simulation results include modal response, pressure distribution in the auditory canal and displacement distribution in the tympanic membrane. The identified modal frequencies of the auditory canal agree with published data reported in the literature. The validation of such method with standard FEM simulation at increasing mesh density shows that FEM is more suitable for simulations of the human ear in the audible frequency range, although the generalized formulation could be convenient if an ear model including the whole head or the ultrasound frequency range were investigated. %U https://www.sv-jme.eu/sl/article/finite-element-formulations-applied-to-outer-ear-modeling/ %0 Journal Article %R 10.5545/sv-jme.2014.1837 %& 363 %P 10 %J Strojniški vestnik - Journal of Mechanical Engineering %V 60 %N 5 %@ 0039-2480 %8 2018-06-28 %7 2018-06-28
Volandri, Gaia, Constantino Carmignani, Francesca Di Puccio, & Paola Forte. "Finite Element Formulations Applied to Outer Ear Modeling." Strojniški vestnik - Journal of Mechanical Engineering [Online], 60.5 (2014): 363-372. Web. 20 Dec. 2024
TY - JOUR AU - Volandri, Gaia AU - Carmignani, Constantino AU - Di Puccio, Francesca AU - Forte, Paola PY - 2014 TI - Finite Element Formulations Applied to Outer Ear Modeling JF - Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2014.1837 KW - finite element method, auditory canal, simulation, sound transmission N2 - The work described in this paper is part of a broader research activity on the development of a virtual ear. The present study focuses on the tympanic membrane and auditory canal modeling, which are important components in sound transmission. The standard finite element method (FEM) and an alternative method (the generalized FEM), suitable for modeling sound propagation at high frequencies, were applied. Two domains (fluid and structural) for the auditory canal and the tympanic membrane, respectively, were considered in order to evaluate the coupling of the different methods and to apply a fluid-structure interaction formulation. ANSYS® software was used for solving FEM analyses, while GFEM simulations were obtained by implementing the method in Wolfram Mathematica®. Simulation results include modal response, pressure distribution in the auditory canal and displacement distribution in the tympanic membrane. The identified modal frequencies of the auditory canal agree with published data reported in the literature. The validation of such method with standard FEM simulation at increasing mesh density shows that FEM is more suitable for simulations of the human ear in the audible frequency range, although the generalized formulation could be convenient if an ear model including the whole head or the ultrasound frequency range were investigated. UR - https://www.sv-jme.eu/sl/article/finite-element-formulations-applied-to-outer-ear-modeling/
@article{{sv-jme}{sv-jme.2014.1837}, author = {Volandri, G., Carmignani, C., Di Puccio, F., Forte, P.}, title = {Finite Element Formulations Applied to Outer Ear Modeling}, journal = {Strojniški vestnik - Journal of Mechanical Engineering}, volume = {60}, number = {5}, year = {2014}, doi = {10.5545/sv-jme.2014.1837}, url = {https://www.sv-jme.eu/sl/article/finite-element-formulations-applied-to-outer-ear-modeling/} }
TY - JOUR AU - Volandri, Gaia AU - Carmignani, Constantino AU - Di Puccio, Francesca AU - Forte, Paola PY - 2018/06/28 TI - Finite Element Formulations Applied to Outer Ear Modeling JF - Strojniški vestnik - Journal of Mechanical Engineering; Vol 60, No 5 (2014): Strojniški vestnik - Journal of Mechanical Engineering DO - 10.5545/sv-jme.2014.1837 KW - finite element method, auditory canal, simulation, sound transmission N2 - The work described in this paper is part of a broader research activity on the development of a virtual ear. The present study focuses on the tympanic membrane and auditory canal modeling, which are important components in sound transmission. The standard finite element method (FEM) and an alternative method (the generalized FEM), suitable for modeling sound propagation at high frequencies, were applied. Two domains (fluid and structural) for the auditory canal and the tympanic membrane, respectively, were considered in order to evaluate the coupling of the different methods and to apply a fluid-structure interaction formulation. ANSYS® software was used for solving FEM analyses, while GFEM simulations were obtained by implementing the method in Wolfram Mathematica®. Simulation results include modal response, pressure distribution in the auditory canal and displacement distribution in the tympanic membrane. The identified modal frequencies of the auditory canal agree with published data reported in the literature. The validation of such method with standard FEM simulation at increasing mesh density shows that FEM is more suitable for simulations of the human ear in the audible frequency range, although the generalized formulation could be convenient if an ear model including the whole head or the ultrasound frequency range were investigated. UR - https://www.sv-jme.eu/sl/article/finite-element-formulations-applied-to-outer-ear-modeling/
Volandri, Gaia, Carmignani, Constantino, Di Puccio, Francesca, AND Forte, Paola. "Finite Element Formulations Applied to Outer Ear Modeling" Strojniški vestnik - Journal of Mechanical Engineering [Online], Volume 60 Number 5 (28 June 2018)
Strojniški vestnik - Journal of Mechanical Engineering 60(2014)5, 363-372
© The Authors, CC-BY 4.0 Int. Change in copyright policy from 2022, Jan 1st.
The work described in this paper is part of a broader research activity on the development of a virtual ear. The present study focuses on the tympanic membrane and auditory canal modeling, which are important components in sound transmission. The standard finite element method (FEM) and an alternative method (the generalized FEM), suitable for modeling sound propagation at high frequencies, were applied. Two domains (fluid and structural) for the auditory canal and the tympanic membrane, respectively, were considered in order to evaluate the coupling of the different methods and to apply a fluid-structure interaction formulation. ANSYS® software was used for solving FEM analyses, while GFEM simulations were obtained by implementing the method in Wolfram Mathematica®. Simulation results include modal response, pressure distribution in the auditory canal and displacement distribution in the tympanic membrane. The identified modal frequencies of the auditory canal agree with published data reported in the literature. The validation of such method with standard FEM simulation at increasing mesh density shows that FEM is more suitable for simulations of the human ear in the audible frequency range, although the generalized formulation could be convenient if an ear model including the whole head or the ultrasound frequency range were investigated.