2002
DOI: 10.1250/ast.23.195
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An overview of the physiology, physics and modeling of the sound source for vowels.

Abstract: The vibration of the vocal folds produces the primary sound source for vowels. This paper first reviews vocal fold anatomy and the kinematics associated with typical vibratory motion. A brief historical background is then presented on the basic physics of vocal fold vibration and various efforts directed at mathematical modeling of the vocal folds. Finally, a low-dimensional model is used to simulate the vocal fold vibration under various conditions of vocal tract loading. In particular, a ''notract'' case is … Show more

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Cited by 92 publications
(45 citation statements)
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“…9 Sustained vowels generated under controlled F0 and intensity and not disturbed by articulatory adjustments elicit a stationary process resulting in a linear source-filter coupling, which reflects the sound power produced by the vocal folds, therefore enhancing the chances of identifying effects for research purposes. 5,9,10,[22][23][24] However, there is inconsistency in the literature as to which vowels are most stable with regard to objective acoustic measurements. For example, authors disagree regarding differences related to acoustic perturbation measurements of vowels.…”
Section: Introductionmentioning
confidence: 99%
“…9 Sustained vowels generated under controlled F0 and intensity and not disturbed by articulatory adjustments elicit a stationary process resulting in a linear source-filter coupling, which reflects the sound power produced by the vocal folds, therefore enhancing the chances of identifying effects for research purposes. 5,9,10,[22][23][24] However, there is inconsistency in the literature as to which vowels are most stable with regard to objective acoustic measurements. For example, authors disagree regarding differences related to acoustic perturbation measurements of vowels.…”
Section: Introductionmentioning
confidence: 99%
“…This is often referred to as the mucosal wave (Story, 2002), or vertical phase difference. Figure 1 depicts a cycle of vocal fold vibration in the coronal plane.…”
Section: Normal Modes In Vocal Fold Oscillationmentioning
confidence: 99%
“…Following Story (2002), simulations from the two-mass model will be analyzed in the next sections using two conditions of vocal tract loading. In a first "setup" we assume that no vocal tract load is present, so that the vocal tract input pressure is atmospheric (p v ≡ 0): this roughly corresponds to the configuration 9 of excised larynges typically used for experimental measures.…”
Section: Vocal Tract Loadmentioning
confidence: 99%
“…This cover tissue allows a surface wave (mucosal wave) to be generated on the vocal fold surface. This mucosal wave propagates longitudinally along the axis of airflow during phonation 9 …”
Section: Vocal Fold Structure and Functionmentioning
confidence: 99%