Pressure Distributions in Glottal Geometries With Multichannel Airflows.

IF 2.5 4区医学 Q1 AUDIOLOGY & SPEECH-LANGUAGE PATHOLOGY

Journal of Voice Pub Date : 2024-09-16 DOI:10.1016/j.jvoice.2024.08.019

Ingo R Titze, Lynn Maxfield, Brian Manternach, Anil Palaparthi, Ronald Scherer, Xiaojian Wang, Xudong Zheng, Qian Xue

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引用次数: 0

Abstract

Objectives: Computer simulation of self-sustained oscillation of the vocal folds has been successful with application of simple Bernoulli-like driving pressures. As voice simulation is now applied to asymmetric vibration with complex mode structures that yield partial vocal fold contact, the driving pressures need refinement.

Study design and methodology: Two independent approaches were used to obtain pressure distributions. The first was a high-fidelity immersed-boundary method computation and the second was a series of pressure tap measurements on scaled-up physical models. Glottal geometries were based on normal surface modes of vibration. Samples are chosen from a large inventory of measured and calculated profiles.

Results: Pressure distributions show the complexity that can exist in the driving forces on vocal fold surfaces. Qualitative similarity between computation and measurement was established for a variety of contact patterns, showing diverse pressure gradients in multiple directions.

Conclusions: Simplified Bernoulli approaches to glottal pressure distributions are defensible when a single flow channel is preserved in vocal fold oscillation. However, when there are contact islands that produce confluence or difluence of multiple airflow channels, the pressure gradients vary profoundly. Small quantitative differences were observed between measurement and calculation, primarily due to spatial sampling.

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多通道气流在声门几何结构中的压力分布

目的：利用简单的伯努利驱动压力对声带自持振荡进行计算机模拟已经取得了成功。由于嗓音模拟现在适用于具有复杂模态结构的非对称振动，会产生部分声带接触，因此需要对驱动压力进行改进：研究设计和方法：我们采用了两种独立的方法来获取压力分布。研究设计：采用了两种独立的方法来获取压力分布，第一种是高保真沉浸边界法计算，第二种是在按比例放大的物理模型上进行一系列压力测量。声门几何形状基于法向表面振动模式。样本选自大量测量和计算的剖面图：结果：压力分布显示了声带表面驱动力的复杂性。对于各种接触模式，计算与测量之间建立了定性相似性，显示出多个方向上的不同压力梯度：结论：当声带摆动中保留单一流道时，简化的伯努利声门压力分布方法是可行的。然而，当接触岛产生多个气流通道的汇合或分流时，压力梯度就会发生很大变化。测量与计算之间存在微小的定量差异，这主要是由于空间取样造成的。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Voice 医学-耳鼻喉科学

CiteScore

4.00

自引率

13.60%

发文量

395

审稿时长

59 days

期刊介绍： The Journal of Voice is widely regarded as the world''s premiere journal for voice medicine and research. This peer-reviewed publication is listed in Index Medicus and is indexed by the Institute for Scientific Information. The journal contains articles written by experts throughout the world on all topics in voice sciences, voice medicine and surgery, and speech-language pathologists'' management of voice-related problems. The journal includes clinical articles, clinical research, and laboratory research. Members of the Foundation receive the journal as a benefit of membership.