Modal locking between vocal fold and vocal tract oscillations: Experiments and statistical analysis

The human vocal folds are known to interact with the vocal tract acoustics during voiced speech production; namely a nonlinear source-filter coupling has been observed both by using models and in \emph{in vivo} phonation. These phenomena are approached from two directions in this article. We first present a computational dynamical model of the speech apparatus that contains an explicit filter-source feedback mechanism from the vocal tract acoustics back to the vocal folds oscillations. The model was used to simulate vocal pitch glideswhere the trajectory was forced to cross the lowest vocal tract resonance, i.e., the lowest formant $F_1$. Similar patterns produced by human participants were then studied. Both the simulations and the experimental results reveal an effect when the glides cross the first formant (as may happen in \textipa{[i]}). Conversely, this effect is not observed if there is no formant within the glide range (as is the case in \textipa{[\textscripta]}). The experiments show smaller effect compared to the simulations, pointing to an active compensation mechanism.