From Nowhere to Everywhere: The Inbetweenness in Henry James's Works after the New York Edition / 「どこにも」から「どこでも」へ　――ニューヨーク版後の作品におけるヘンリー・ジェイムズの中間的帰属意識について

Takei, Tomoko

23 January 2020

京都大学 / 0048 / 新制・論文博士 / 博士(人間・環境学) / 乙第13306号 / 論人博第52号 / 新制||人||219(附属図書館) / 2019||論人博||52(吉田南総合図書館) / 京都大学大学院人間・環境学研究科文化・地域環境学専攻 / (主査)教授 水野 尚之, 教授 廣野 由美子, 准教授 小島 基洋, 教授 中川 優子 / 学位規則第4条第2項該当 / Doctor of Human and Environmental Studies / Kyoto University / DGAM

Henry James

inbetweenness

The Finer Grain

The Sense of the Past

The Ivory Tower

361

Modélisation biomécanique de l'interaction tendon-aponévrose-fibre pour estimer les forces musculaires : apport des mesures échographiques

Gérus, Pauline épouse Daussant

26 September 2011

L'estimation des forces musculaires nécessite le développement d'un modèle biomécanique. Une des étapes essentielle de ce type d'approche est la modélisation de l'interaction au sein du complexe muscle-tendon entre trois composants, les fibres musculaires, l'aponévrose et le tendon par un modèle de type Hill. L'objectif de ce travail doctoral était d'identifier les paramètres dans le modèle de type Hill qui jouent un rôle important dans l'estimation des forces musculaires et de proposer une méthode pour les définir. L’échographie a été utilisée pour estimer la relation force-déformation in vivo du tendon et de l'aponévrose, et le comportement in vivo des fibres musculaires au cours de la contraction pour chaque sujet et comme un moyen de quantifier la précision des modèles en mesurant le comportement in vivo des fibres musculaires et les comparer aux sorties du modèle. L'utilisation d'une définition de l'Élément Élastique en série spécifique au sujet dans les modèles biomécaniques joue un rôle important pour des activités où les forces musculaires sont importantes. Lors de tâches isométriques maximales, la relation force-déformation du tendon spécifique au sujet combiné à des contraintes sur la géométrie initiale conduit à des estimations de forces musculaires plus faibles et un comportement différent des fibres. En ce qui concerne des activités comme le hopping et la course, l’utilisation d’une relation force-déformation du complexe tendon-aponévrose spécifique au sujet permet d’estimer des forces musculaires plus grandes et entraîne un découplage du comportement des fibres musculaires plus important par rapport au complexe muscle-tendon. Pour des activités de marche, la définition de l’élément en série dans le modèle de type-Hill n'influence pas les forces musculaires. L'échographie apparaît comme un outil intéressant pour personnaliser les modèles et pourrait être appliqué sur des patients ayant un trouble neuromusculosquelettique. / The estimation of forces produced by the muscle-tendon complex around a joint needs the development of a neuromusculoskeletal model. One of essential step of this approach is the modeling by a Hill-type muscle model of the interaction within the muscle-tendon complex between three components: the muscle fiber, the aponeurosis, and the tendon. The objective of this work was to identify the parameters used as input into Hill-type muscle model that play an important role in muscle force estimation and to propose a method to define them. The ultrasonography has been used to estimate in vivo tendon and aponeurosis force-strain relationships, and the in vivo behavior of muscle fiber during the contraction for each subject. In addition, a method was proposed to quantify the model accuracy by estimating the in vivo behavior of muscle fiber and compare it with model outputs. The use of subject-specific definition of Series Elastic Element into the EMG-driven model plays an important role for activity at high level of muscle forces. During maximal isometric contraction, the subject-specific tendon force-strain relationship combined with constraint on initial muscle geometry (i.e., fiber length and muscle thickness) leads to lower estimated muscle forces and to a different behavior for the muscle fiber. Concerning highly dynamic tasks such as running and \textit{hopping}, the use of subject specific force-strain relationship for the tendon-aponeurosis complex allows to estimate higher muscle forces and leads to a heavier decoupling behavior between muscle fiber and muscle-tendon complex.The estimation of forces produced by the muscle-tendon complex needs the development of a neuromusculoskeletal model. One of essential step of this approach is the modeling by a Hill-type muscle model of the interaction within the muscle-tendon complex between three components: the muscle fiber, the aponeurosis, and the tendon. The objective of this work was to identify the parameters used as input into Hill-type muscle model that play an important role in muscle force estimation and to propose a method to define them. The ultrasonography has been used to estimate in vivo tendon and aponeurosis force-strain relationships, and the in vivo behavior of muscle fiber during the contraction for each subject. In addition, a method was proposed to quantify the model accuracy by estimating the in vivo behavior of muscle fiber and compare it with model outputs. The use of subject-specific definition of Series Elastic Element into the EMG-driven model plays an important role for activity at high level of muscle forces. During maximal isometric contraction, the subject-specific tendon force-strain relationship combined with constraint on initial muscle geometry (fiber length and muscle thickness) leads to lower estimated muscle forces and to a different behavior for the muscle fiber. Concerning highly dynamic tasks such as running and hopping, the use of subject specific force-strain relationship for the tendon-aponeurosis complex allows to estimate higher muscle forces and leads to a heavier decoupling behavior between muscle fiber and muscle-tendon complex. Concerning dynamic tasks with low force level such as walking, the estimation of muscle force was not influenced by the Series Elastic Element definition. The ultrasonography appears as a useful tool to personalize neuromusculoskeletal models and could be used for patient with neuromusculoskeletal disorders showing an alteration of tendon mechanical properties allowing to quantify the effect of rehabilitation program.

Échographie

Élément élastique en série

Fibre musculaire

EMG-driven model

Hill-type muscle model

Ultrasound

Series elastic elemtn

Muscle finer

On The Effect Of Material Uncertainty And Matrix Cracks On Smart Composite Plate

Umesh, K

07 1900

Recent developments show the applications of smart structure in different engineering fields. Smart structures can be used for shape and vibration control, structural health monitoring etc. Smart materials can be integrated to composite structure to enhance its abilities. Fiber reinforced composites are the advanced materials of choice in aerospace applications due to its high strength and stiffness, light weight and ability to tailor according to the design requirements. Due to complex manufacturing process and varying operating conditions, composites are susceptible to variation in material properties and damages. The present study focuses on the effect of uncertainties in material properties and damages on a smart composite structure. A cantilevered composite plate with surface mounted piezoelectric sensor/ actuator is considered in this study. The sensors and the actuators are connected through a conventional feedback controller and the controller is configured for vibration control application. Matrix cracks are considered as damage in the composite plate. To study the effect of material uncertainty, probabilistic analysis is performed considering composite material properties and piezoelectric coefficients as independent Gaussian random variables. Numerical results show that there is substantial change in dynamic response of the smart composite plate due to material uncertainties and damage. Deviation due to material uncertainty and damage can be compensated by actively tuning the feedback control system. Feedback control parameters can be properly adjusted to match the baseline response. Here baseline case represents the response of the undamaged smart composite plate with deterministic material properties. The change in feedback control parameters are identified as damage indicator. Feedback control based damage detection method is proposed for structural health monitoring in smart composite structure and robustness of the method is studied considering material uncertainties. Fractal dimension based damage detection method is proposed to detect localized matrix cracks in a composite plate with spatially varying material properties. Variation in material properties follows a two dimensional homogeneous Gaussian random field. Fractal dimension is used to extract the damage information from the static response of composite plate with localized matrix cracks. It is found that fractal dimension based approach is capable of detecting the location of the single and multiple damages from the static deflection curve. Robustness of the fractal dimension based damage detection method is studied considering spatial uncertainties in material properties.

Structural Engineering

Composite Materials

Smart Composite Plates

Matrix Cracks

Composite Plates

Finer Reinforced Composites

Material Uncertainty

Composite Structures

Matrix Crack Detection

Smart Composite Materials

Composite Material Uncertainty

Smart Composite Structures

Materials Science