publication . Article . Preprint . 2002

modeling vocal fold motion with a hydrodynamic semicontinuum model

LaMar, M. Drew; Qi, Yingyong; Xin, Jack;
Open Access
  • Published: 18 Jan 2002 Journal: The Journal of the Acoustical Society of America, volume 114, pages 455-464 (issn: 0001-4966, Copyright policy)
  • Publisher: Acoustical Society of America (ASA)
Abstract
Comment: 27 pages,6 figures
Subjects
arXiv: Physics::Fluid Dynamics
free text keywords: Compressible flow, Inviscid flow, Physics, Flow separation, Bernoulli's principle, Navier–Stokes equations, Internal flow, Mechanics, Compressibility, Euler system, Nonlinear Sciences - Pattern Formation and Solitons, Nonlinear Sciences - Adaptation and Self-Organizing Systems
27 references, page 1 of 2

[1] K. Ishizaka, J. L. Flanagan, Synthesis of Voiced Sounds From a Two-Mass Model of the Vocal Cords, ATT Bell System Tech Journal, Vol. 51, No. 6, 1233-1268 (1972). [OpenAIRE]

[3] B. Story, I. Titze, Voice simulation with a body-cover model of the vocal folds, Journal of the Acoustic Soc. Am., 97(2), 1249-1260 (1995). [OpenAIRE]

[4] D. Wong, M. Ito, N. Cox, I. Titze, Observation of perturbations in a lumped-element model of the vocal folds with application to some pathological cases, J. Acoust. Soc. Am. 89(1), 383-394 (1991).

[5] I. Titze, The human vocal cords: A mathematical model, part I, Phonetica, 28, 129-170 (1973).

[6] I. Titze, The human vocal cords: A mathematical model, part II, Phonetica, 29, 1-21 (1974).

[7] F. Alipour, D. Berry, I. Titze, A finite-element model of vocal fold vibration, J. Acous. Soc. Am, 108(6), 3003-3012 (2000). [OpenAIRE]

[8] X. Pelorson, A. Hirschberg, A. Wijnands, H. Bailliet, Description of the flow through invitro models of the glottis during phonation, Acta Acustica 3, 191-202, (1995).

[9] J. Flanagan, Speech Analysis, Synthesis and Perception, 2nd Edition, Springer-Verlag, New York, Berlin, 1972.

[10] L. Mongeau, N. Franchek, C. Coker, R. Kubil, Characteristics of a pulsating jet through a small modulated oriface, with applications to voice production, J. Acoust. Soc Am, 102(2), 1121-1132 (1997).

[11] F. Alipour, R. Scherer, J. Knowles, Velocity Distribution in Glottal Models, Journal of Voice, Vol. 10, No. 1, 50-58 (1996).

[12] I. Titze, Current Topics in Voice Production Mechanisms, Acta Otolaryngol, 113, 421-427 (1993).

[13] J. Jiang, I. Titze, Measurement of vocal fold intraglottal pressure and impact stress, J. Voice, 8, 132-144 (1994).

[14] S. Austin, I. Titze, The Effect of Subglottal Resonance Upon Vocal Fold Vibration, Journal of Voice, Vol. 11, No. 4, 391-402 (1997).

[15] T-Y Hsiao, N. Soloman, E. Luschei, I. Titze, K. Liu, T-C Fu, M-M Hsu, Effect of Subglottal Pressure on Fundamental Frequency of the Canine Larynx with Active Muscle Tensions, Ann. Otol. Rhinol. Laryngol. 103, 817-821 (1994). [OpenAIRE]

[16] D. Moore, G. Burke, The effect of laryngeal nerve stimulation on phonation: a glottographic study using an in vivo canine model, J. Acoust. Soc. Am 83, pp 705-715(1988).

27 references, page 1 of 2
Powered by OpenAIRE Open Research Graph
Any information missing or wrong?Report an Issue
publication . Article . Preprint . 2002

modeling vocal fold motion with a hydrodynamic semicontinuum model

LaMar, M. Drew; Qi, Yingyong; Xin, Jack;