Full text loading...
No data available.
Please log in to see this content.
You have no subscription access to this content.
No metrics data to plot.
The attempt to load metrics for this article has failed.
The attempt to plot a graph for these metrics has failed.
Medial surface dynamics of an in vivo canine vocal fold during phonation
1.P. Mergell, H. Herzel, and I. Titze, “Irregular vocal-fold vibration—high speed observation and modelling,” J. Acoust. Soc. Am. 108, 2996–3002 (2000).
2.J. G. Svec, J. Horacek, F. Sram, and J. Vesely, “Resonance properties of the vocal folds: In vivo laryngoscopic investigation of the externally excited laryngeal vibrations,” J. Acoust. Soc. Am. 108, 1397–1407 (2000).
3.M. Döllinger, T. Braunschweig, J. Lohscheller, U. Eysholdt, and U. Hoppe, “Normal voice production: Computation of driving parameters from endoscopic digital high speed images,” Methods Inf. Med. 42, 271–276 (2003).
4.E. Schönhärl, Die Stroboskopie in Der Praktischen Laryngologie (Thieme-Verlag, Stuttgart, 1960).
5.I. R. Titze, “Parametrization of the glottal area, glottal flow, and vocal fold contact area,” J. Acoust. Soc. Am. 75, 570–580 (1984).
6.Y. C. Fung, Biomechanics: Mechanical Properties of Living Tissues (Springer-Verlag, New York, 1993).
7.R. Wilhemls-Tricarico, “Physiological modeling of speech production: methods for modeling soft tissue articulators,” J. Acoust. Soc. Am. 97, 3085–3098 (1995).
8.P. Mergell and H. Herzel, “Modelling biphonation—the role of the vocal tract,” Speech Commun. 22, 141–154 (1997).
9.M. P. de Vries, H. K. Schutte, and G. J. Verkerke, “Determination of parameters for lumped parameter models of the vocal folds using a finite-element method approach,” J. Acoust. Soc. Am. 106, 3620–3628 (1999).
10.F. Alipour, D. A. Berry, and I. R. Titze, “A finite element model of vocal fold vibration,” J. Acoust. Soc. Am. 108, 3003–3012 (2000).
11.E. J. Hunter, I. R. Titze, and F. Alipour, “A three-dimensional model of vocal fold abduction/adduction,” J. Acoust. Soc. Am. 115, 1747–1759 (2004).
12.T. Baer, “Investigation of phonation using excised larynges,” Ph.D. thesis, Massachusetts Institute of Technology, Boston, MA, 1975.
13.S. Saito, H. Fukuda, S. Kitahira, Y. Tsuzuki, H. Muta, E. Takayama, T. Fujika, N. Kokawa, and K. Makino, “Pellet tracking in the vocal fold while phonating: experimental study using canine larynges with muscle activity,” in Vocal Fold Physiology, edited by I. R. Titze and R. C. Scherer (Denver Center for the Performing Arts, Denver, CO, 1985), pp. 169–182.
14.J. J. Jiang and I. R. Titze, “A methodological study of hemilaryngeal phonation,” Laryngoscope 103, 872–882 (1993).
15.G. M. Gardner, J. Castracane, M. Conerty, and S. M. Parnes, “Electronic speckle pattern interferometry of the vibrating larynx,” Ann. Otol. Rhinol. Laryngol. 104, 5–12 (1995).
16.D. A. Berry, D. W. Montequin, and N. Tayama, “High-speed digital imaging of the medial surface of the vocal folds,” J. Acoust. Soc. Am. 110, 2539–2545 (2001).
17.D. A. Berry, H. Herzel, I. R. Titze, and K. Krischer, “Interpretation of biomechanical simulations of normal and chaotic vocal fold oscillations with empirical eigenfunctions,” J. Acoust. Soc. Am. 95, 3595–3604 (1994).
18.G. S. Berke and B. R. Gerratt, “Laryngeal biomechanics: An overview of mucosal wave mechanics,” J. Voice 7, 123–128 (1993).
19.F. Alipour-Haghighi and I. R. Titze, “Elastic models of vocal fold tissues,” J. Acoust. Soc. Am. 90, 1326–1331 (1991).
20.M. Döllinger and D. A. Berry, “Computation of the three-dimensional medial surface dynamics of the vocal folds,” J. Biomech. (in press).
21.M. Döllinger and D. A. Berry, “Three-dimensional medical surface dynamics of the vocal folds using high-speed digital imaging,” in Proceedings of the 26th World Congress of the International Association of Logopedics and Phoniatrics (Speech Pathology Australia, Melbourne—Australia, 2004), p. CD.
22.G. S. Berke, D. M. Moore, P. A. Monkewitz, D. G. Hanson, and B. R. Garrett, “A preliminary study of particle velocity during phonation in an in vivo canine model,” J. Voice 3, 306–313 (1989).
23.S. Bielamowicz, G. S. Berke, J. Kreiman, and B. R. Gerratt, “Exit jet particle velocity in the in vivo canine laryngeal model with variable nerve stimulation,” J. Voice 13, 153–160 (1999).
24.M. Hirano, “Structure and vibratory behavior of the vocal folds,” in Dynamic Aspects of Speech Production, edited by M. Sawashima and S. Franklin (Univ. of Tokyo, Tokyo, 1977), pp. 13–30.
25.Y. I. Abdel-Aziz and H. M. Karara, “Direct linear transformation from comparator coordinates into object space coordinates in close-range photogrammetry,” in Proceedings of the Symposium on Close-Range Photogrammetry (American Society of Photogrammetry, Falls Church, VA, 1971), pp. 1–18.
26.J. Lohscheller, M. Döllinger, M. Schuster, U. Eysholdt, and U. Hoppe, “ The laryngectomee substitute voice: Image processing of endoscopic recordings by fusion with acoustic signals,” Methods Inf. Med. 42, 277–281 (2003).
27.N. R. Miller, R. Shapiro, and T. M. McLaughlin, “A technique for obtaining spatial kinematic parameters of segments of biomechanical systems from cinematographic data,” J. Biomech. 13, 535–547 (1980).
28.H. Hatze, “High-precision three-dimensional photogrammetric calibration and object reconstruction using a modified DLT-approach,” J. Biomech. 15, 11–19 (1988).
29.L. Chen, C. W. Armstrong, and D. D. Raftopoulos, “An investigation on the accuracy of three-dimensional space using the Direct Linear Transformation,” J. Biomech. 27, 493–500 (1994).
30.Y. Xunhua and L. Ryd, “Accuracy analysis for RSA: a computer simulation on 3D marker reconstruction,” J. Biomech. 30, 493–498 (2000).
31.G. A. Wood and R. N. Marshall, “The accuracy of DLT extrapolation in three-dimensional film analysis,” J. Biomech. 19, 781–785 (1986).
32.A. M. T. Choo and T. R. Oxland, “Improved RSA accuracy with DLT and balanced calibration marker distributions with an assessment of initial-calibration,” J. Biomech. 36, 259–264 (2003).
33.W. Murray, Numerical Methods for Unconstrained Optimization (Academic, London, 1972).
34.G. Golub and C. V. Loan, Matrix Computations, 2nd ed. (The John Hopkins University, Baltimore, MD, 1989).
35.M. Döllinger, U. Hoppe, F. Hettlich, J. Lohscheller, S. Schuberth, and U. Eysholdt, “Vocal fold parameter extraction using the two-mass-model,” IEEE Biomed. Eng. 49, 773–781 (2002).
36.J. Neubauer, P. Mergell, U. Eysholdt, and H. Herzel, “Spatio-temporal analysis of irregular vocal fold oscillations: Biphonation due to desynchronization of spatial modes,” J. Acoust. Soc. Am. 110, 3179–3192 (2001).
37.S. N. Nasri, P. Dulguerov, J. Damrose, M. Ye, J. Kreiman, and G. S. Berke, “Relation of recurrent laryngeal nerve compound action potential to laryngeal biomechanics,” Laryngoscope 105, 639–643 (1995).
38.M. Hirano, “Morphological structure of the vocal cord as a vibrator and its variations,” Folia Phoniatr. 26, 89–94 (1974).
39.M. Hirano, “Phonosurgery: Basic and clinical investigations,” Otologia (Fukuoka) 21, 239–440 (1975).
40.I. R. Titze, J. Jiang, and D. Druker, “Preliminaries to the body-cover theory of pitch control.,” J. Voice 1, 314–319 (1988).
41.I. R. Titze, Principles of Voice Production (Prentice–Hall, Englewood Cliffs, NJ, 1994).
42.T. Baer, “Investigation of the phonatory mechanism,” ASHA Report 11, 1981, pp. 38
43.K. S. Breuer and L. Sirovich, “The use of the Karhunen–Loeve procedure for the calculation of linear eigenfunctions,” J. Comput. Phys. 96, 277–296 (1991).
44.I. R. Titze, “The physics of small-amplitude oscillation of the vocal folds,” J. Acoust. Soc. Am. 83, 1536–1551 (1988).
45.T. Riede, H. Herzel, D. Mehwald, W. Seidner, E. Trumler, G. Böhme, and G. Tembrock, “Nonlinear phenomena in the natural howling of a dog–wolf mix,” J. Acoust. Soc. Am. 108, 1435–1442 (2000).
46.I. Sanders, Y. Han, J. Wang, and H. Biller, “Muscle spindles are concentrated in the superior vocalis subcompartment of the human thyroarytenoid muscle,” J. Voice 12, 7–16 (1998).
Article metrics loading...