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A Fast, Passive and Accurate Model Generation Algorithm for RLCG Transmission Lines with Skin EffectsChen, Yuan 27 September 2005 (has links)
No description available.
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Robust Nonlinear Estimation and Control of Clutch-to-Clutch ShiftsMishra, Kirti D. 08 June 2016 (has links)
No description available.
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Sparse Methods for Model Estimation with Applications to Radar ImagingAustin, Christian David 19 June 2012 (has links)
No description available.
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Modeling, Parametrization, and Diagnostics for Lithium-Ion Batteries with Automotive ApplicationsMarcicki, James Matthew 19 December 2012 (has links)
No description available.
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Randomization for Efficient Nonlinear Parametric InversionSariaydin, Selin 04 June 2018 (has links)
Nonlinear parametric inverse problems appear in many applications in science and engineering. We focus on diffuse optical tomography (DOT) in medical imaging. DOT aims to recover an unknown image of interest, such as the absorption coefficient in tissue to locate tumors in the body. Using a mathematical (forward) model to predict measurements given a parametrization of the tissue, we minimize the misfit between predicted and actual measurements up to a given noise level. The main computational bottleneck in such inverse problems is the repeated evaluation of this large-scale forward model, which corresponds to solving large linear systems for each source and frequency at each optimization step. Moreover, to efficiently compute derivative information, we need to solve, repeatedly, linear systems with the adjoint for each detector and frequency. As rapid advances in technology allow for large numbers of sources and detectors, these problems become computationally prohibitive. In this thesis, we introduce two methods to drastically reduce this cost.
To efficiently implement Newton methods, we extend the use of simultaneous random sources to reduce the number of linear system solves to include simultaneous random detectors. Moreover, we combine simultaneous random sources and detectors with optimized ones that lead to faster convergence and more accurate solutions.
We can use reduced order models (ROM) to drastically reduce the size of the linear systems to be solved in each optimization step while still solving the inverse problem accurately. However, the construction of the ROM bases still incurs a substantial cost. We propose to use randomization to drastically reduce the number of large linear solves needed for constructing the global ROM bases without degrading the accuracy of the solution to the inversion problem.
We demonstrate the efficiency of these approaches with 2-dimensional and 3-dimensional examples from DOT; however, our methods have the potential to be useful for other applications as well. / Ph. D. / Medical image reconstruction presents huge computational challenges due to the quantity of data generated by modern equipment. Each stage of processing requires the solution of more than a thousand large, three-dimensional problems. Moreover, as rapid advances in technology allow for ever larger numbers of sources and detectors and using multiple frequencies, these problems become computationally prohibitive. In this thesis, we develop two computational methods to drastically reduce this cost and produce good images from measurements.
First, we focus on efficiently estimating the absorption image while we reduce the cost of each optimization step by solving only for a few linear combinations of sources and of detectors.
Second, we can replace the full mathematical model by a reduced mathematical model to drastically reduce the size of the linear systems in each optimization step while still producing good image reconstructions. However, the computation of this reduced model still poses a formidable cost. Hence, we propose to reduce the cost of building the reduced model by sampling the sources and detectors. Using this reduced model for image reconstruction does not degrade the accuracy of the solutions and the quality of the image reconstruction.
We demonstrate the efficiency of these approaches with 2-dimensional and 3-dimensional examples from medical imaging. However, our methods have the potential to be useful for other applications as well.
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Study on Error Estimation of the Cauer Ladder Network Method / カウア回路法の誤差推定に関する研究Nagamine, Hideaki 25 March 2024 (has links)
付記する学位プログラム名: 京都大学卓越大学院プログラム「先端光・電子デバイス創成学」 / 京都大学 / 新制・課程博士 / 博士(工学) / 甲第25292号 / 工博第5251号 / 新制||工||1999(附属図書館) / 京都大学大学院工学研究科電気工学専攻 / (主査)教授 松尾 哲司, 教授 萩原 朋道, 教授 阪本 卓也 / 学位規則第4条第1項該当 / Doctor of Agricultural Science / Kyoto University / DGAM
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Electromagnetic Modeling of High-Speed Interconnects with Frequency Dependent Conductor Losses, Compatible with Passive Model Order Reduction TechniquesPasha, Soheila January 2012 (has links)
A computationally efficient, discrete model is presented for transmission line analysis and passive model order reduction of high-speed interconnect systems. The development of this model was motivated by the on-going efforts in chip/package co-design to route a major portion of the on-chip clock and high-speed data buses through the package in order to overcome the bandwidth reduction and delay caused by the high ohmic loss of on-chip wiring. The geometric complexity of the resulting interconnections is such that model order reduction is essential for rapid and accurate signal integrity assessment to support pre-layout design iteration and optimization. The modal network theory of the skin effect in conjunction with the theory of compact differences is used for the development of discrete models for dispersive, multi-conductor interconnects compatible with passive model order reduction algorithms. The passive reduced-order interconnect modeling algorithm, PRIMA, is then used on the resulting discrete model to generate a low-order, multi-port macromodel for interconnect networks. Numerical examples are used to demonstrate the validity and efficiency of the proposed model.
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Étude basée sur l’optimisation fiabiliste en aérodynamique / Study based on reliability optimization in aerodynamicsEl Maani, Rabii 22 October 2016 (has links)
Le domaine de l'interaction fluide-structure regroupe l'étude de tous les phénomènes présentant le couplage du mouvement d'une structure avec celui d'un fluide. La gamme des phénomènes étudiés est très étendue, allant de l'étude de cylindres vibrants dans des écoulements comme c'est le cas dans l'industrie nucléaire, à des structures vibrantes dans des écoulements turbulents, en passant par des phénomènes de surface libre dans des réservoirs. Cependant, la complexité des phénomènes étudiés se répercute par des coûts de calculs prohibitifs, ce qui nous amène à rechercher des modèles réduits dont le temps de calcul serait plus réaliste. Dans cette thèse, on va présenter les différents modèles d'interaction fluide-structure et on va mettre en avant le modèle adopté dans notre étude. La réduction du modèle ainsi que l'optimisation des structures vont être introduites dans un contexte de couplage. En introduisant les incertitudes, l'étude fiabiliste de même qu'une approche d'optimisation basée fiabilité vont être proposées. Les différentes méthodologies adoptées vont être validées numériquement et comparées expérimentalement / The domain of the fluid-structure interaction includes the study of all phenomena presenting the coupling of the motion of a structure with the one of a fluid. The range of the phenomena being studied is very extensive, going from the study of vibrating cylinders in the flow as is the case in the nuclear industry, to vibrating structures in turbulent flows, through the free surface phenomena in reservoirs. However, the complexity of the phenomena studied is reflected by the cost of the prohibitive calculations, which leads us to look for models with the computation time would be more realistic. In this thesis, we will present different models of fluid-structure interaction and we will put forward the model adopted in our study. Reducing the model as well as the optimization of the structures will be introduced into a coupling setting. By introducing uncertainties, the reliability study as well as an optimization based reliability approach will be proposed. The different methodologies adopted will be validated numerically and experimentally compared
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Methods for including stiffness parameters from reduced finite element models in simulations of multibody systemsFjellstedt, Christoffer January 2019 (has links)
Two methods using lumped element (lumped parameter) methods to model flexible bodies have been presented. The methods are based on the concept of using a Guyan reduced stiffness matrix to describe the elasticity of a body. The component to be modeled has been divided into two parts using FE software and the mass and inertia tensor for the respective part of the component have been retrieved. The first method has been based on including the elements from the stiffness matrix in compliant constraints. The compliant constraints have been derived and a prototype has been implemented in MATLAB. It has been shown that using compliant constraints and stiffness parameters from a Guyan reduced stiffness matrix it is possible, with highly accurate results, to describe the deformation of a flexible body in multibody simulations. The second method is based on springs and dampers and has been implemented in the simulation environment Dymola. The springs and dampers have been constructed to include coupling elements from a Guyan reduced stiffness matrix. It has been shown that using the proposed method it is possible, with highly accurate results, to describe the static deformation of a flexible body. Further, using dynamic simulations of a full robot manipulator model, it has been shown that it is possible to use the spring-damper model to capture the deformation of the links of a manipulator in dynamic simulations with large translations and rotations.
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Modélisation et simulation des connexions intra et inter systèmes électroniques / Modeling and simulation of interconnects within and between electronic systemsIassamen, Nadia 03 December 2013 (has links)
Les progrès constants en miniaturisation des transistors et l’augmentation des fréquences des signaux utilisés sont les principales tendances dans l’évolution des circuits électroniques. Avec ces évolutions apparaissent de nombreux effets indésirables qui perturbent le comportement des systèmes électroniques et sont soupçonnés d’être responsables de la majorité des dégradations de signaux dans les systèmes en haute fréquence. Des retards de propagation indésirables sont ainsi introduits par la présence des interconnexions, et la diaphonie, phénomène dû aux couplages entre lignes d’interconnexions, peut éventuellement provoquer des commutations non désirées des transistors. La prise en compte des interconnexions, dès les premières phases de conception d'un système, est par conséquent devenue une nécessité ces dernières années. Mais la simulation temporelle d’un réseau d’interconnexions est très gourmande en temps de calcul, ce qui impacte la durée globale de conception. Le remplacement des modèles électriques, décrivant précisément les interconnexions, par des modèles plus simples est primordial pour limiter les coûts de calcul. Une méthode de réduction d'ordre des modèles peut alors être employée pour effectuer cette opération efficacement. Le modèle final doit en effet décrire assez précisément certains aspects importants du modèle original et conserver les propriétés importantes du réseau d'interconnexions. Cette démarche permettra aux concepteurs d’effectuer des simulations temporelles rapides et d’étudier les paramètres d’intégrité du signal tel que le retard, le temps de montée, le dépassement….L'objectif de cette thèse est d’établir un nouvel outil de réduction de complexité des modèles de réseaux d'interconnexions. Différentes descriptions initiales des systèmes d'interconnexions sont envisagées : modèles circuits (fonctions de transfert) ou mesures fréquentielles. L’approche développée repose sur l’utilisation des fonctions orthogonales de Müntz-Laguerre et de Kautz afin de décrire mathématiquement, de manière précise, le système d'origine. Un opérateur linéaire, lié à ces fonctions de base, est ensuite appliqué pour déterminer un modèle rationnel de moindre complexité. La technique proposée est comparée à d'autres méthodes de la littérature d’abord sur des exemples académiques. Tout le potentiel de la méthode est ensuite illustré par sa mise en œuvre sur des réseaux d'interconnexions. / The ongoing progress in transistor miniaturization and a continuous frequency increase are the main trends in the present day evolution of electronic circuits. A number of undesired effects are intrinsic to these developments and are suspected to be responsible for most of the flawed signals present in high frequency systems. Parasitic delays are thus introduced by the presence of interconnect lines and crosstalk due to coupling may lead to undesired switching events in transistor circuits. Accounting for the presence of interconnect lines, at a very early stage in the design flow has become unavoidable in recent years. However, time domain simulations of massively coupled interconnect networks may be computationally costly and have a tremendous impact on the overall duration of the design process. Replacing complex, high order circuit models by more compact surrogates is thus necessary. Model order reduction is an effective way to derive such surrogates. The final model must mimic certain aspects of the original model with sufficient accuracy and preserve the interconnect network’s most important properties. This approach enables designers to account for the undesired effects of interconnect lines such as, delays, rise-times and overshoots while maintaining the overall duration of time-domain simulations within acceptable limits. The aim of this thesis is to create a new model order reduction tool applicable to complex interconnect networks. Different initial representations were considered – circuit models (transfer functions) or frequency domain measurements. The proposed approach uses orthogonal basis functions such as Müntz-Laguerre and Kautz to build an accurate mathematical representation of the original system .A linear operator, related to these functions, is subsequently used to derive a simplified model. The technique is first compared to other approaches using examples available in literature, its full potential being demonstrated on coupled interconnect models.
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