声带如何在有限的黏膜波中发生振动？

How can vocal folds oscillate with a limited mucosal wave?

机构信息

Utah Center for Vocology, University of Utah, Salt Lake City, Utah 84112, USA

出版信息

JASA Express Lett. 2022 Oct;2(10):105201. doi: 10.1121/10.0014359.

DOI:10.1121/10.0014359

PMID:36319212

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9533394/

Abstract

Self-sustained vocal fold vibration is possible with either or both of two mechanisms: (1) a mucosal wave propagating along the medial surface of the vocal folds and (2) a vocal tract that offers inertive reactance. A quantitative comparison shows the mucosal wave mechanism has a lower threshold pressure and a higher glottal efficiency, but the supraglottal inertance mechanism can assist in the oscillation and is effective in optimizing the two mechanisms. It is concluded that optimal parameters are a mucosal wave velocity on the order of 1 m/s and a diameter of the larynx canal (epilarynx tube) on the order of 0.8 cm.

摘要

声带的自主振动可能通过以下两种机制中的任一种或两种来实现

（1）沿声带内表面传播的黏膜波，以及（2）提供惯性电抗的声道。定量比较表明，黏膜波机制具有较低的阈压和较高的声门效率，但声门上惯性机制有助于振动，并且在优化这两种机制方面是有效的。结论是，最佳参数是黏膜波速度约为 1 m/s，喉管（喉管）直径约为 0.8 cm。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/ed6d/9533394/adad93e97913/JELAAE-000002-105201_1-g001.jpg

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声带如何在有限的黏膜波中发生振动？

How can vocal folds oscillate with a limited mucosal wave?

机构信息

出版信息

声带的自主振动可能通过以下两种机制中的任一种或两种来实现

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