TY - JOUR
T1 - Using a biomechanical model and articulatory data for the numerical production of vowels
AU - Dabbaghchian, Saeed
AU - Arnela, Marc
AU - Engwall, Olov
AU - Guasch, Oriol
AU - Stavness, Ian
AU - Badin, Pierre
N1 - Publisher Copyright:
Copyright © 2016 ISCA.
PY - 2016
Y1 - 2016
N2 - We introduce a framework to study speech production using a biomechanical model of the human vocal tract, ArtiSynth. Electromagnetic articulography data was used as input to an inverse tracking simulation that estimates muscle activations to generate 3D jaw and tongue postures corresponding to the target articulator positions. For acoustic simulations, the vocal tract geometry is needed, but since the vocal tract is a cavity rather than a physical object, its geometry does not explicitly exist in a biomechanical model. A fully-automatic method to extract the 3D geometry (surface mesh) of the vocal tract by blending geometries of the relevant articulators has therefore been developed. This automatic extraction procedure is essential, since a method with manual intervention is not feasible for large numbers of simulations or for generation of dynamic sounds, such as diphthongs. We then simulated the vocal tract acoustics by using the Finite Element Method (FEM). This requires a high quality vocal tract mesh without irregular geometry or self-intersections. We demonstrate that the framework is applicable to acoustic FEM simulations of a wide range of vocal tract deformations. In particular we present results for cardinal vowel production, with muscle activations, vocal tract geometry, and acoustic simulations.
AB - We introduce a framework to study speech production using a biomechanical model of the human vocal tract, ArtiSynth. Electromagnetic articulography data was used as input to an inverse tracking simulation that estimates muscle activations to generate 3D jaw and tongue postures corresponding to the target articulator positions. For acoustic simulations, the vocal tract geometry is needed, but since the vocal tract is a cavity rather than a physical object, its geometry does not explicitly exist in a biomechanical model. A fully-automatic method to extract the 3D geometry (surface mesh) of the vocal tract by blending geometries of the relevant articulators has therefore been developed. This automatic extraction procedure is essential, since a method with manual intervention is not feasible for large numbers of simulations or for generation of dynamic sounds, such as diphthongs. We then simulated the vocal tract acoustics by using the Finite Element Method (FEM). This requires a high quality vocal tract mesh without irregular geometry or self-intersections. We demonstrate that the framework is applicable to acoustic FEM simulations of a wide range of vocal tract deformations. In particular we present results for cardinal vowel production, with muscle activations, vocal tract geometry, and acoustic simulations.
KW - Biomechanical articulatory model
KW - Finite Element Method
KW - Speech production
KW - Vocal tract acoustics
KW - Vocal tract geometry
UR - http://www.scopus.com/inward/record.url?scp=84994364959&partnerID=8YFLogxK
U2 - 10.21437/Interspeech.2016-1500
DO - 10.21437/Interspeech.2016-1500
M3 - Conference article
AN - SCOPUS:84994364959
SN - 2308-457X
VL - 08-12-September-2016
SP - 3569
EP - 3573
JO - Proceedings of the Annual Conference of the International Speech Communication Association, INTERSPEECH
JF - Proceedings of the Annual Conference of the International Speech Communication Association, INTERSPEECH
T2 - 17th Annual Conference of the International Speech Communication Association, INTERSPEECH 2016
Y2 - 8 September 2016 through 16 September 2016
ER -