3D synthetic aperture PIV measurements from artificial vibrating vocal folds

TL;DR

This paper demonstrates a novel 3D visualization technique using Synthetic aperture PIV to analyze the pulsatile jet from vibrating vocal folds, enhancing understanding of speech mechanics and voice disorders.

Contribution

It introduces a new application of SAPIV for reconstructing the three-dimensional flow from artificial vocal fold vibrations, enabling detailed flow analysis.

Findings

Successful 3D reconstruction of vocal fold jet

First visualization of pulsatile jet in speech research

Potential to improve voice disorder diagnosis

Abstract

During speech, air from the lungs is forced past the vocal folds which vibrate, producing sound. A pulsatile jet of air is formed downstream of the vibrating folds which interacts with the various structures in the airway. Currently, it is postulated that the way this jet interacts with the downstream structures in the airway directly affects the quality of human speech. In order to better understand this jet, it is desirable to visualize the jet in three dimensions. We present the results of a method that reconstructs the three dimensional velocity field using Synthetic aperture PIV (SAPIV) \cite{Belden:2010}. SAPIV uses an array of high-speed cameras to artificially create a single camera with a variable focal length. This is accomplished by overlapping the images from the array to create a "focal stack". As the images are increasingly overlapped, more distant image planes come into focus. 3D PIV is then performed on the "refocused" focal stack to reconstruct the flow field in three dimensions. SAPIV has the ability to track very high particle densities. Artificial self oscillating vocal folds made of silicone were driven with compressed air infused with small glass microspheres. As the vocal folds vibrated, the entrained microspheres were illuminated by a laser volume. Eight high-speed cameras were used to capture images of the particles for SAPIV postprocessing. SAPIV was able to successfully perform the first whole-field reconstruction of the pulsatile jet emerging from the vocal folds. The ability to visualize this jet will help researchers and clinicians better understand the physics of speech production as well as improve the prevention, diagnosis, and treatment of voice disorders.