Global ETD Search

1	Internal Deformation Measurements and Optimization of Synthetic Vocal Fold Models Taylor, Cassandra Jeanne 01 December 2018 (has links) Developing lifelike vocal fold models is challenging due to various associatedbiomechanical complexities. Nevertheless, the development and analysis of improved vocal foldmodels is worthwhile since they are valuable tools for gaining insight into human vocal foldvibratory, aerodynamic, and acoustic response characteristics. This thesis seeks to contribute tothe development of computational and physical vocal fold modeling in two ways. First is byintroducing a method of obtaining internal deformation fields within vibrating synthetic vocal foldmodels; second is by presenting an optimization algorithm coupled with a computational vocalfold model to optimize geometry and stiffness of a synthetic vocal fold model to achieve morerealistic vibration patterns.The method for tracking the internal deformation of self-oscillating vocal fold models isbased on MR imaging. Silicone models scaled to four times life-size to lower the flow-inducedvibration frequency were imbedded with fiducial markers in a coronal plane. Candidate markermaterials were tested using static specimens, and two materials, cupric sulfate and glass, werechosen for testing in the vibrating VF models. The vibrating models were imaged using a gatedMRI protocol wherein MRI acquisition was triggered using the subglottal pressure signal. Twodimensionalimage slices at different phases during self-oscillation were captured, and in eachphase the fiducial markers were clearly visible. The process was also demonstrated using a threedimensionalscan at two phases. The benefit of averaging to increase signal-to-noise ratio wasexplored. The results demonstrate the ability to use MRI to acquire quantitative deformation datathat could be used, for example, to validate computational models of flow-induced VF vibrationand quantify deformation fields encountered by cells in bioreactor studies.A low fidelity, two-dimensional, finite element model of VF flow-induced vibration wascoupled with a custom MATLAB-based genetic algorithm optimizer. The objective was to achievea closed quotient within the normal human physiological range. The results showed that changesin geometry and stiffness would lead to a model that exhibited the desired characteristics. Aphysical model based on optimized parameters was then fabricated and the closed quotient wastested. The physical model successfully vibrated with nonzero closed quotient as predicted by thecomputational model. vocal folds MRI gating optimization genetic algorithm fluid-structure interaction vocal fold modeling Mechanical Engineering
2	Development and Analysis of 3D-Printed Synthetic Vocal Fold Models Romero, Ryan Gregory 01 August 2019 (has links) Vocal fold models are valuable for studying voice production. They provide an alternative method of studying the mechanics of the voice that does not require in vivo experimentation or the use of excised human or animal tissue. In this thesis, a new method of creating vocal fold models through additive manufacturing is described. The purpose of this research was to reduce model fabrication time, to decrease the number of model failures during manufacturing, and to lay the foundation for creating models with more lifelike geometric and material properties. This research was conducted in four stages. First, a suitable silicone additive manufacturing technique using a UV-curable silicone was chosen. The technique chosen was called freeform reversible embedding (FRE) and involved embedding liquid silicone material into a gel-like medium named organogel. The UV-curable silicone's material properties were identified to confirm its utility in vocal fold model design. Second, an open-source, fused deposition modeling slicing software was selected to create g-code for the printer. Applicable software settings were tuned through qualitative printing tests to find their optimal values for use in FRE printing. Third, 3D-printed cubes were used in tensile tests to characterize the material properties of FRE-printed, silicone material. The cubes were found to be anisotropic, exhibiting different modulus values corresponding to the layer orientation of the printed material. Fourth, vocal fold models were FRE-printed in two different layer orientations and were used in phonation tests to gather data for onset pressure, vibratory frequency, amplitude, and flow rate. The printed models self-oscillated and withstood the strains induced by phonation. These tests showed that layer direction affects the phonation properties of the models, demonstrating that models with layers in the coronal plane had slightly lower frequencies and onset pressures than models with layers in the sagittal plane. The models' onset pressures were higher than what is found in human vocal folds. However, their frequencies were within a comparable range. These tests showed the effectiveness of additive manufacturing in the application of vocal fold fabrication, reducing production effort by allowing researchers to go directly from model design to fabrication in a single manufacturing step. It is anticipated that this method will be modified to incorporate printing of multiple stiffnesses of silicone to better mimic the material properties of vocal fold tissue, and that the anisotropy of 3D-printed material will be leveraged to model the anisotropy of human vocal folds. This work also has potential application areas outside of voice research. silicone 3D printing vocal folds voice research additive manufacturing vocal fold modeling Engineering
3	Modeling Vocal Fold Intravascular Flow with Synthetic Replicas Terry, Aaron David 01 September 2018 (has links) (PDF) Communication by voice is foundational in our society and many rely on their voices for their occupations. Voice disorders affect a significant number of individuals each year, and diagnosis and treatment improvements are therefore sought via advancements in voice research. Contained in this thesis is a description of work intended to contribute to vocal fold research by using synthetic, self-oscillating vocal fold replicas to study the impact of replica vibration on perfusion fluid flow through the replica. Methods for manufacturing vocal fold replicas containing imbedded channels allowing for fluid perfusion are discussed. Experimental procedures developed for delivering perfusion fluid to the imbedded channel at a constant pressure during replica vibration are described. Methods for measuring perfusion parameters of perfusion fluid pressure, imbedded channel diameter, flow rate, and vibration parameters (subglottal pressure, frequency, amplitude, channel length, and glottal width) are detailed. Experiments performed using both stationary and vibrating vocal fold replicas are presented. Correlations between perfusion pressure and channel diameter are discussed. Vibration parameters were correlated to perfusion flow parameters and it is shown that perfusion flow rate through the channels decreased significantly with model vibration. Potential mechanisms for changes in perfusion flow resistance with vibration are discussed and analyzed. Output of a theoretical model, developed to incorporate some of the possible flow resistance mechanisms, was compared to vibrating replica experimental data. vocal folds vocal fold vasculature vocal fold modeling experimental measurements fluid flow rate Mechanical Engineering
4	Influence of Subglottic Geometry on Computational and Synthetic Vocal Fold Model Vibration Smith, Simeon L. 10 August 2011 (has links) (PDF) The voice plays a vital role in human communication. The purpose of voice research is to advance the understanding of voice production physics, with the ultimate goal of leading to improved voice care. In this research computational and synthetic vocal fold models were used to explore the role of subglottal geometry in vocal fold vibration. Three specific studies were performed. First, the effect of the inferior vocal fold surface angle on voice production was investigated using a two-dimensional self-oscillating finite element vocal fold model. Varying the inferior angle resulted in significant changes to model vibratory motion, glottal width, flow rate, and energy transfer. The changes were attributed primarily to changes in structural, rather than aerodynamic, factors. Second, subglottic stenosis (SGS) was introduced and parametrically varied in a similar computational model to determine the influence of SGS on vocal fold vibration. High severities of SGS influenced several factors related to vibration, including glottal width, flow rate, flow resistance, and vibration frequency. Subglottal pressure distributions and flow patterns were also affected. Third, the response of a self-oscillating silicone vocal fold model to varying degrees of SGS in an experimental setup was studied. Consistent with the computational SGS study, SGS had an effect on the synthetic model response at high severities. Changes were seen particularly in subglottal pressure and radiated acoustic sound, and consequently glottal efficiency, which may have important implications regarding the effect of SGS on the human voice. vocal folds vocal fold modeling subglottis inferior surface angle subglottic stenosis Simeon L. Smith Mechanical Engineering
5	Évolution tectonique du Tianshan oriental du Néogène à l'actuel / Tectonic evolution of eastern Tianshan from Neogene to present Saint-Carlier, Dimitri 09 October 2015 (has links) Le Tianshan est une orogène intracontinentale de près de 2000 km de long. Cette chaîne accommode jusqu'à 40% de la convergence entre l'Inde et l'Eurasie, jouant ainsi un rôle fondamental dans l'évolution de la déformation en Asie. De plus, malgré cette déformation intense et ses hauts reliefs, sa topographie reste irrégulière avec de nombreux bassins intrachaîne préservés. Elle représente ainsi un cas remarquable pour l'étude des processus orogéniques dynamiques hors équilibre et constitue une zone clé pour l'étude de la déformation en Asie. Depuis le début du Pléistocène, une aridité prononcée a permis une préservation de nombreux marqueurs morphologiques. Ces marqueurs ont localement subi des déformations d'origine tectonique. Ainsi, la datation par isotopes cosmogéniques de ces marqueurs et la quantification du raccourcissement à l'origine de leur déformation, a permis de connaître précisément les vitesses de raccourcissements quaternaires de nombreuses structures actives au travers l'ensemble du Tianshan oriental. À cela s'ajoutent ponctuellement des études des vitesses de raccourcissement depuis le Néogène, basées sur la modélisation géométrique de strates syntectoniques. Ces mesures nous ont permis de mieux contraindre les taux de déformation sur les piémonts Nord et Sud de la chaîne mais également dans le bassin intrachaîne de Bayanbuluk. Sur la base de ces observations, je propose que les vitesses observées actuellement par les mesures GPS ne soient acquises par la chaîne que depuis ~150 à 200 ka. Nous démontrons aussi qu'au minimum 15% du raccourcissement est accommodé dans les parties internes de la chaîne. Je soutiens ainsi l'hypothèse que cette chaîne reste dans un stade de croissance immature et hors-équilibre / The Tianshan range is a 2000-km-long tectonically active mountain range. The Tianshan plays a major role in the India-Asia collision since it presently accommodates up to 40% of the total convergence between those two continents. Despite this intense deformation, the topography of the range shows series of high elevated range separated by flat intermountain basins. This range is therefore a remarkable case of example to study orogenesis processes and remains a key area to better understand how the deformation related to the India collision has been distributed through the Asian continent. Enhanced aridity since Pleistocene has moreover remarkably preserved alluvial terraces and fans which may have recorded the deformation enabling the quantification of the tectonic rates during the Quaternary period. Therefore, using Terrestrial Cosmogenic Nuclide we have dated several alluvial surfaces and analyzed their deformation using D.E.M. or high resolution DGPS measurements. Hence, in the eastern Tianshan we quantify the quaternary shortening rates across several structures located in the Northern and Southern foreland piedmonts but also within the range in the intermountain Bayanbuluk basin. Moreover, when possible we have also derived the Neogene shortening rates from geometric modeling of syntectonic strata. Our results highlight the recent acceleration of the eastern Tianshan since ~150-200 ka. We also show that a significant proportion (>15%) of the whole deformation is accommodated within the range while the remaining part is distributed between the different thin skin tectonic structure in the piedmonts. This result supports the hypothesis that the range is out of equilibrium and an in-building stage of deformation Tianshan Tectonique Terrasse alluviale Datations par isotopes cosmogéniques Modélisation de plissement Tianshan Tectonic Alluvial terrace Cosmogenic nuclide dating Fold modeling 551.8
6	Pressures and Flows for a Convergent and Divergent Oblique Glottis of 15 Degrees Whitfield, Jason A. 04 April 2012 (has links) No description available. Biomechanics Biophysics Civil Engineering Engineering Speech Therapy Glottal Asymmetries Vocal Fold Asymmetries Vocal Fold Physiology Glottal Aerodynamics Vocal Fold Modeling
7	Development of a 3D Computational Vocal Fold Model Optimization Tool Vaterlaus, Austin C. 09 June 2020 (has links) One of the primary objectives of voice research is to better understand the biomechanics of voice production and how changes in properties of the vocal folds (VFs) affect voice ability and quality. Synthetic VF models provide a way to observe how changes in geometry and material property affect voice biomechanics. This thesis seeks to evaluate an approach of using a genetic algorithm to design synthetic VF models in three ways: first, through the development of a computationally cost-effective 3D vocal fold model; second, by creating and optimizing a variation of this model; and third, by validating the approach. To reduce computation times, a user-defined function (UDF) was implemented in low-fidelity 2D and 3D computational VF models. The UDF replaced the conventional meshed fluid domain with the mechanical energy equation. The UDF was implemented in the commercial finite element code ADINA and verified to produce results that were similar to those of 2D and 3D VF models with meshed fluid domains. Computation times were reduced by 86% for 2D VF models and 74% for 3D VF models while core vibratory characteristic changes were less than 5%. The results from using the UDF demonstrate that computation times could be reduced while still producing acceptable results. A genetic algorithm optimizer was developed to study the effects of altering geometry and material elasticity on frequency, closed quotient (CQ), and maximum flow declination rate (MFDR). The objective was to achieve frequency and CQ values within the normal human physiological range while maximizing MFDR. The resulting models enabled an exploration of trends between objective and design variables. Significant trends and aspects of model variability are discussed. The results demonstrate the benefit of using a structured model exploration method to create models with desirable characteristics. Two synthetic VF models were fabricated to validate predictions made by models produced by the genetic algorithm. Fabricated models were subjected to tests where frequency, CQ, and sound pressure level were measured. Trends between computational and synthetic VF model responses are discussed. The results show that predicted frequency trends between computational and synthetic models were similar, trends for closed quotient were inconclusive, and relationships between MFDR and sound pressure level remained consistent. Overall, while discrepancies between computational and synthetic VF model results were observed and areas in need of further study are noted, the study results provide evidence of potential for using the present optimization method to design synthetic VF models. vocal folds user defined function optimization genetic algorithm vocal fold modeling maximum flow declination rate voice production synthetic vocal fold models flow-induced vibration fluid-structure interactions Engineering
8	Geometry and Material Properties of Vocal Fold Models Stevens, Kimberly Ann 01 July 2015 (has links) (PDF) Voiced communication plays a fundamental role in society. Voice research seeks to improve understanding of the fundamental physics governing voice production, with the eventual goal of improving methods to diagnose and treat voice disorders. For this thesis, three different aspects of voice production research were studied. First, porcine vocal fold medial surface geometry was determined, and the three-dimensional geometric distortion induced by freezing the larynx, especially in the region of the vocal folds, was quantified. It was found that porcine vocal folds are qualitatively geometrically similar to canine and human vocal folds, as well as commonly used models, and that freezing of tissue in the larynx causes distortion of around 5%. Second, a setup of multiple high-resolution cameras and a stereo-endoscopy system simultaneously recorded positions on the superior surface of synthetic, self-oscillating vocal fold models to estimate the error in the measurement of the three-dimensional location by the stereo-endoscopy system. The error was found to be low in the transverse plane, whereas the error was relatively large in the inferior-superior direction, suggesting that the stereo-endoscope is applicable for in vivo measurements of absolute distances of the glottis in the transverse plane such as glottal length, width, and area. Third, a function for strain-varying Poisson's ratio for silicone was developed from experimental data. It is anticipated that the findings herein can aid voice researchers as they study voice production, leading to improved voice care. vocal folds porcine vocal folds vocal fold medial surface geometry tissue distortion histological processing vocal fold modeling Poisson's ratio stereo-endoscopy image processing Mechanical Engineering
9	Influence of Material and Geometric Parameters on the Flow-Induced Vibration of Vocal Folds Models Pickup, Brian A. 13 July 2010 (has links) (PDF) The vocal folds are an essential component of human speech production and communication. Advancements in voice research allow for improved voice disorder treatments. Since in vivo analysis of vocal fold function is limited, models have been developed to simulate vocal fold motion. In this research, synthetic and computational vocal fold models were used to investigate various aspects of vocal fold vibratory characteristics. A series of tests were performed to quantify the effect of varying material and geometric parameters on the models' flow-induced responses. First, the influence of asymmetric vocal fold stiffness on voice production was evaluated using life-sized, self-oscillating vocal fold models with idealized vocal fold geometry. Asymmetry significantly influenced glottal jet flow, glottal area, and vibration frequency. Second, flow-induced responses of simplified and MRI-based synthetic models were compared. The MRI-based models showed remarkable improvements, including less vertical motion, alternating convergent-divergent glottal profile patterns, and mucosal wave-like movement. Third, a simplified model was parametrically investigated via computational modeling techniques to determine which geometric features influenced model motion. This parametric study led to identification and ranking of key geometric parameters based on their effects on various measures of vocal fold motion (e.g., mucosal wavelike movement). Incorporation of the results of these studies into the definition of future models could lead to models with more life-like motion. vocal folds vocal fold modeling asymmetry mucosal wave high-speed imaging particle image velocimetry PIV MRI parameterization videokymography VKG Brian A. Pickup Mechanical Engineering
10	Flow-induced Responses of Normal, Bowed, and Augmented Synthetic Vocal Fold Models Murray, Preston Roylance 10 August 2011 (has links) (PDF) The voice is the primary mode of communication for humans. Because the voice is so important, voice disorders tend to severely diminish quality of life. A better understanding of the physics of voice production can help to improve treatment of voice disorders. For this thesis research a self-oscillating synthetic vocal fold model was developed, compared with previous synthetic vocal fold models, and used to explore the physical effects of augmentation injections on vibration dynamics. The research was conducted in two stages. First, four vocal fold models were evaluated by quantifying onset pressure, frequency, maximum glottal gap, flow rate, and medial surface motion. The newly developed model, differentiated from the other models by the inclusion of more layers, adjusted geometry, and an extremely soft superficial lamina propria layer, was included in this study. One of the models, created using MRI-derived geometry, had the most defined mucosal wave. The newly-developed model had the lowest onset pressure, flow rate, and smallest maximum glottal width, and the model motion compared very well with published excised human larynx data. Second, the new model was altered to simulate bowing by decreasing the volume of the body layer relative to that of a normal, unbowed model. Two models with varying degrees of bowing were created and tested while paired with normal models. Pre- and post-injection data (onset pressure, vibration frequency, glottal flow rate, open quotient, and high-speed image sequences) were recorded and compared. General pre- to post-injection trends included decreased onset pressure, glottal flow rate, and open quotient, and increased vibration frequency. Additionally, there was a decrease in mucosal wave velocity and an increase in phase angle. The thesis results are anticipated to aid in better understanding the physical effects of augmentation injections, with the ultimate goal of obtaining more consistent surgical outcomes, and also to contribute to the advancement of voice research through the development of the new synthetic model. vocal folds vocal fold modeling mucosal wave high-speed imaging injection laryngoplasty larynx medial surface augmentation Preston R. Murray Mechanical Engineering

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