Abstract
Excised larynges serve as natural models for studying behavior of the voice source. Acoustic resonances inside the air-supplying tubes below the larynx (i.e., subglottal space), however, interact with the vibratory behavior of the larynges and obscure their inherent vibration properties. Here, we explore a newly designed anechoic subglottal space which allows removing its acoustic resonances. We performed excised larynx experiments using both anechoic and resonant subglottal spaces in order to analyze and compare, for the very first time, the corresponding subglottal pressures, electroglottographic and radiated acoustic waveforms. In contrast to the resonant conditions, the anechoic subglottal pressure waveforms showed negligible oscillations during the vocal fold contact phase, as expected. When inverted, these waveforms closely matched the inverse filtered radiated sound waveforms. Subglottal resonances modified also the radiated sound pressures (Level 1 interactions). Furthermore, they changed the fundamental frequency (fo) of the vocal fold oscillations and offset phonation threshold pressures (Level 2 interactions), even for subglottal resonance frequencies 4–10 times higher than fo. The obtained data offer the basis for better understanding the inherent vibratory properties of the vocal folds, for studying the impact of structure-acoustic interactions on voice, and for validation of computational models of voice production.
Highlights
Excised larynges serve as natural models for studying behavior of the voice source
The newly developed anechoic subglottal tract successfully removed its acoustic resonances to suppress their influence on vocal fold vibrations
When used in excised larynx experiments, the subglottal acoustic pressure waveform was similar to the inverted glottal flow source signal: almost constant during the closed phase, decreasing during the opening phase and increasing during the closing phase
Summary
Excised larynges serve as natural models for studying behavior of the voice source. Acoustic resonances inside the air-supplying tubes below the larynx (i.e., subglottal space), interact with the vibratory behavior of the larynges and obscure their inherent vibration properties. The well-known source-filter theory proposed by Gunnar Fant[1] described the voice production mechanism as a sound source (the exhalatory air flow modulated by vocal fold vibrations), filtered by acoustic resonances in the supraglottal cavities above the vocal folds (i.e. vocal tract resonances), and supposed no interaction between the source and the filter. Excised larynges with a newly developed anechoic (resonance-free) subglottal tract[22] This setup eliminates the acoustic interactions with both the vocal and subglottal tracts and allows studying the vibration properties of the vocal folds in their inherent state. The vocal fold vibrations were simultaneously monitored by the electroglottographic (EGG) signal, which is an approximate measure of the changes in the vocal fold contact area[24,25] In these experiments, we compared the subglottal pressure waveforms and investigated the influence of the subglottal acoustics on the vocal fold vibrations and on the radiated sound
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