Multiconductor transmission line analysis using surface ribbon method /

Kim, Sangwoo,

January 1999

Thesis (Ph. D.)--University of Texas at Austin, 1999. / Vita. Includes bibliographical references (leaves 93-99). Available also in a digital version from Dissertation Abstracts.

Multiconductor transmission lines.

Modeling and characterization of multiple coupled lines

Tripathi, Alok

02 April 1999

A configuration-oriented circuit model for multiple coupled lines in an inhomogeneous medium is developed and presented in this thesis. This circuit model consists of a network of uncoupled transmission lines and is readily modeled with simulation tools like LIBRA�� and SPICE��. It provides an equivalent circuit representation which is simple and topologically meaningful as compared to the model based on modal decomposition. The configuration-oriented model is derived by decomposing the immittance matrices associated with an n coupled line 2n-port system. Time- and frequency-domain simulations of typical coupled line multiports are included to exemplify the utility of the model. The model is useful for the simulation and design of general single and multilayer coupled line components, such as filters and couplers, and for the investigation of signal integrity issues including crosstalk in interconnects associated with high speed digital and mixed signal electronic modules and packages. It is shown that multiconductor lossless structures in an inhomogeneous medium can be characterized by multiport time-domain reflection (TDR) measurements. A synthesis technique of an equivalent lossless (non-dispersive) uniform multiconductor n coupled lines (UMCL) 2n-port system from the measured discrete time-domain reflection response is presented. This procedure is based on the decomposition of the characteristic immittance matrices of the UMCL in terms of partial mode immittance matrices. The decomposition scheme leads to the discrete transition matrix function of a UMCL 2n-port system. This in turn establishes a relationship between the normal-mode parameters of the UMCL and the measured impulse reflection and transmission response. Equivalence between the synthesis procedure presented in this thesis and the solution of a special form of an algebraic Riccati matrix equation whose solution can lead to the normal-mode parameters and a real termination network is illustrated. In order to demonstrate the procedure, a typical microstrip structure with three lines is synthesized from the time-domain reflection (TDR) data. In order to compliment known field theoretic techniques for characterization of multiconductor structures a network analog method is employed to solve the magnetic vector potential equation to characterize multilayer Metal-Insulator-Semiconductor (MIS) transmission line structures. This approach leads to the frequency dependent distributed inductance and the resistance matrices of a multilayer MIS transmission line structure. It is shown that the frequency dependent transmission line parameters can be modeled by an efficient quasi-static formulation for all propagating modes including the slow-wave and skin-effect modes. To demonstrate the proposed approach for single and multilevel structures, the frequency dependent distributed inductance and resistance matrices corresponding to the propagating modes classified as the slow-wave and skin-effect modes are calculated and validated by comparison with full-wave solutions. / Graduation date: 1999

Theory and Applications of Multiconductor Transmission Line Analysis for Shielded Sievenpiper and Related Structures

Elek, Francis

15 February 2011

This thesis focuses on the analytical modeling of periodic structures which contain bands with multiple modes of propagation. The work is motivated by several structures which exhibit dual-mode propagation bands. Initially, transmission line models are focused on. Transmission line models of periodic structures have been used extensively in a wide variety of applications due to their simplicity and the ease with which one can physically interpret the resulting wave propagation effects. These models, however, are fundamentally limited, as they are only capable of capturing a single mode of propagation. In this work multiconductor transmission line theory, which is the multi-mode generalization of transmission line theory, is shown to be an effective and accurate technique for the analytical modeling of periodically loaded structures which support multiple modes of propagation. Many results from standard periodic transmission line analysis are extended and generalized in the multiconductor line analysis, providing a familiar intuitive model of the propagation phenomena. The shielded Sievenpiper structure, a periodic multilayered geometry, is analyzed in depth, and provides a canonical example of the developed analytical method. The shielded Sievenpiper structure exhibits several interesting properties which the multiconductor transmission line analysis accurately captures. It is shown that under a continuous change of geometrical parameters, the dispersion curves for the shielded structure are transformed from dual-mode to single-mode. The structure supports a stop-band characterized by complex modes, which appear as pairs of frequency varying complex conjugate propagation constants. These modes are shown to arise even though the structure is modeled as lossless. In addition to the periodic analysis, the scattering properties of finite cascades of such structures are analyzed and related to the dispersion curves generated from the periodic analysis. Excellent correspondence with full wave finite element method simulations is demonstrated. In conclusion, a physical application is presented: a compact unidirectional ring-slot antenna utilizing the shielded Sievenpiper structure is constructed and tested.

Multiconductor transmission lines

Wave propagation in periodic structures

0544

Theory and Applications of Multiconductor Transmission Line Analysis for Shielded Sievenpiper and Related Structures

Elek, Francis

15 February 2011

This thesis focuses on the analytical modeling of periodic structures which contain bands with multiple modes of propagation. The work is motivated by several structures which exhibit dual-mode propagation bands. Initially, transmission line models are focused on. Transmission line models of periodic structures have been used extensively in a wide variety of applications due to their simplicity and the ease with which one can physically interpret the resulting wave propagation effects. These models, however, are fundamentally limited, as they are only capable of capturing a single mode of propagation. In this work multiconductor transmission line theory, which is the multi-mode generalization of transmission line theory, is shown to be an effective and accurate technique for the analytical modeling of periodically loaded structures which support multiple modes of propagation. Many results from standard periodic transmission line analysis are extended and generalized in the multiconductor line analysis, providing a familiar intuitive model of the propagation phenomena. The shielded Sievenpiper structure, a periodic multilayered geometry, is analyzed in depth, and provides a canonical example of the developed analytical method. The shielded Sievenpiper structure exhibits several interesting properties which the multiconductor transmission line analysis accurately captures. It is shown that under a continuous change of geometrical parameters, the dispersion curves for the shielded structure are transformed from dual-mode to single-mode. The structure supports a stop-band characterized by complex modes, which appear as pairs of frequency varying complex conjugate propagation constants. These modes are shown to arise even though the structure is modeled as lossless. In addition to the periodic analysis, the scattering properties of finite cascades of such structures are analyzed and related to the dispersion curves generated from the periodic analysis. Excellent correspondence with full wave finite element method simulations is demonstrated. In conclusion, a physical application is presented: a compact unidirectional ring-slot antenna utilizing the shielded Sievenpiper structure is constructed and tested.

Multiconductor transmission lines

Wave propagation in periodic structures

0544

Nonlinear transient finite element analysis of conductive and ferromagnetic regions using a surface admittance boundary condition

Wassef, Karim N.

08 1900

No description available.

Multiconductor transmission lines

Time-domain analysis

Electromagnetism Mathematics

Finite element method

Close-form macromodels for analysis of high-speed interconnects in the presence of electromagnetic fields /

Shinh, Gurpreet Singh,

January 1900

Thesis (M.App.Sc.) - Carleton University, 2005. / Includes bibliographical references (p. 115-121). Also available in electronic format on the Internet.

Broadband modelling of high-frequency devices and circuits /

Paul, Douglas

January 1900

Thesis (M.App.Sc.) - Carleton University, 2006. / Includes bibliographical references (p. 103-107). Also available in electronic format on the Internet.

Réflectométrie appliquée à la détection de défauts non francs dans les torons de câbles / Reflectometry applied to soft fault detection in bundles of wires

Franchet, Maud

12 September 2012

Ces travaux de thèse portent sur la détection de défauts non francs dans des structures filaires particulières : les lignes de transmission a multiconducteurs (MTL), aussi appelées torons de câbles. Couramment employées pour le diagnostic de réseaux filaires, les méthodes par réflectométrie ne sont, pour l'heure, pas suffisamment performantes pour détecter de tels défauts. Par ailleurs, elles n'ont, en général, été étudiées et développées que pour des lignes simples, ou les phénomènes de couplages électromagnétiques entre les conducteurs (diaphonie) ne sont pas présents. Ces derniers sont cependant porteurs d'information supplémentaire sur l'état du câble. Les utiliser permettrait d'accroître la sensibilité de détection aux défauts. L'objectif est de proposer une nouvelle méthode de réflectométrie, tirant profit des signaux de diaphonie pour détecter les défauts non francs. Une telle méthode présente également l'avantage d'être adaptée aux structures en toron. Après avoir étudié l'impact d'un défaut non franc sur les paramètres caractéristiques d'une MTL et sur les signaux de diaphonie, une méthode, la "Cluster Time Frequency Domain Reflectometry ", a pu être proposée. Il s'agit d'un procédé en trois étapes. Des mesures par réflectométrie temporelle sont tout d'abord réalisées à l'entrée de la ligne à diagnostiquer. Tous les signaux présents, y compris ceux de diaphonie, sont enregistrés. Un traitement temps-fréquence leur est ensuite appliqué afin d'amplifier la présence d'éventuels défauts. Enfin, un algorithme de clustering, spécifiquement développé pour le diagnostic filaire, est utilisé de manière a bénéficier de l'ensemble de l'information disponible / Research works presented in this thesis rely on detecting soft faults (incipient faults) in specic wiring structures : multiconductor transmission lines (MTL), also known as bundles of wires. Reflectometry methods, often used for the diagnosis of wiring networks, aren't for now efficient enough at detecting such defects. Besides, they have been designed for single lines only, where electromagnetic coupling between conductors (crosstalk) is not to be considered. However such phenomenon can provide more information about the state of the cable. Using this information could enable us to detect soft faults more easily. Our goal is to propose a new reflectometry method, which takes advantage of crosstalk signals in order to detect incipient faults. Such a tool has also the advantage of being well-adapted to bundles of cables. Thanks to the preliminary study of the impact of soft faults on the characteristic parameters of a MTL and on crosstalk signals, a method called "Cluster Time Frequency Domain Reflectometry ", has been proposed. It is a three step process. Firts temporal reflectometry measurements are made at the beginning of the line under test. All the available signals, even crosstalk ones, are recorded. A time-frequency process is then applied on them, in order to amplify the presence of defects. Finally, a clustering algorithm, that has been specically developed for wiring diagnosis, is used to benefit from the whole available information

Réflectométrie

Défauts non francs

Traitement du signal

Fusion de données

Reflectometry

Multiconductor transmission lines

Soft faults

Signal processing

Data fusion

Méthode de modélisation prédictive de boîtiers des circuits intégrés en vue d’anticiper avant design l’immunité au bruit du circuit / predictive modeling method of electronic packages for noise immunity prediction

Bouchaala, Afef

02 December 2016

Avec la miniaturisation de plus en plus poussée des composants sur silicium, certains phénomènes, connus sous le nom des problèmes de la Compatibilité Électromagnétique peuvent surgir, ils sont les principales causes de la reconception des systèmes intégrés. Ce travail de thèse consiste à développer une méthodologie d'analyse prédictive de la compatibilité électromagnétique pour les systèmes électroniques, par anticipation design. Afin d'aboutir à ce modèle prédictif, différents champs d'investigation ont été mise en place afin d'appréhender l'ensemble du problème. Premièrement, nous avons développé une méthode de prédiction des parasites du boîtier électronique appelée « MCTL Matrix Method ». Cette méthode est issue du principe du prototypage virtuel du boîtier et elle est basée sur des lignes de transmission multiconducteurs. Deuxièmement, nous avons proposé une méthodologie d'analyse de l'immunité du système complet dès les premières phases de la conception. / Modern electronic systems require a high-level of integrations. As a result, some phenomena which are known as ElectroMagnetic Compatibility (EMC) issues are arising, and they are the major causes of system redesign. This main objective of this work is to develop a predictive methodology for systems immunity. To do so, different fields have been investigated: first, we have developed a predictive method for package parasites called “MCTL Matrix Method” which is based on a virtual package prototyping and Multiconductor transmission lines. Then we have proposed a new methodology for system immunity at the earliest design stages.

Compatibilité électromagnétique

Analyse prédictive

Prototypage virtuel

Lignes de transmission multiconducteurs

Electromagnetic compatibility

Predictive analysis

Virtual package prototyping

Multiconductor transmission lines

Ondas planas e modais em sistemas distribuídos elétricos e mecânicos

Tolfo, Daniela de Rosso

January 2017

Neste trabalho, são caracterizadas as soluções do tipo ondas planas e modais de modelos matemáticos referentes à teoria de linhas de transmissão, com e sem perdas, e à teoria de vigas, modelo de Timoshenko e modelo não local de Eringen. Os modelos são formulados matricialmente, e as ondas em questão são determinadas em termos da base gerada pela resposta matricial fundamental de sistemas de equações diferenciais ordinárias de primeira, segunda e quarta ordem. A resposta matricial fundamental é utilizada numa forma fechada que envolve o acoplamento de um número finito de matrizes e uma função escalar geradora e suas derivadas. A função escalar geradora é bem comportada para mudanças em torno de frequências críticas e sua robustez é exibida através da técnica de Liouville. As ondas modais são decompostas em termos de uma parte que viaja para frente e uma parte que viaja para trás. Essa decomposição é utilizada para fornecer matrizes de reflexão e transmissão em descontinuidades e condições de contorno. No contexto das linhas de transmissão são consideradas uma junção de linhas com impedâncias características diferentes ou uma carga em uma extremidade da linha. Na teoria de Timoshenko são consideradas uma fissura ou condições de contorno em uma das extremidades. Exemplos numéricos com descontinuidade são considerados na viga. Na teoria de linhas de transmissão exemplos com multicondutores são considerados e observações são realizadas sobre a decomposição das ondas modais. No modelo não local de Eringen, para vigas bi-apoiadas é discutida a existência do segundo espectro de frequências. / Plane type solutions and modal waves of mathematical models, which refer to transmission lines theory, both lossless and lossy, and to beam theory, using both Timoshenko and nonlocal Eringen models, are being characterized in this work. The models are formulated in matrix form, and the waves are determined in terms of matrix basis generated by fundamental matrix response of systems of ordinary differential equations of first, second and fourth order. The fundamental matrix response is used in the closed-form, which involve the coupling between a number finite of matrices of a generating scalar function and its derivatives. The generating scalar function is well behaved for changes around critical frequencies and its robustness is exhibited through the Liouville technique. Modal waves are decomposed in forward and backward parts. This decomposition is used for providing reflection and transmission matrices when dealing with discontinuities and boundary conditions. In the context of transmission lines junction of lines with different characteristic impedances or a load at one end of the line are being considered. In Timoshenko’s theory the crack problem or boundary conditions at one end are also being considered. Numerical examples with discontinuities are considered in the context of beams. Numerical examples with discontinuities and boundary value problems were approached using modal wave decomposition. In transmission line theory examples with multiconductors are considered and observations are made about decomposition of the modal waves. In the nonlocal of Eringen model, for bi-supported beams, the existence of the second frequency spectrum is discussed.

Ondas

Sistemas mecanicos

Multiconductor transmission lines

Reflection and transmission matrix

Boundary and compatibility conditions

Scalar wave generator function

Fundamental matrix solution

Modal waves

Plane waves

Eringen nonlocal model

Timoshenko model