Modal Methods for Modeling and Simulation of Photonic

Mu, Jianwei

04 1900

Optical waveguide structures and devices are the fundamental basic building blocks of photonic cireuits which play important roles in modern telecommunication and sensing systems. With the fast development of fabrication technologies and in response to the needs of miniaturization and fast increased functionality in future integrated photonic chips, various structures based on high-index contrast waveguides, surface plasmonic polaritons structures, etc., have been widely proposed and investigated. Modeling and simulation methods, as efficient and excellent cost performance tools comparing to costly facilities and time-consuming fabrication procedures, are demanded to explore and design the devices and circuits before their finalization. This thesis covers a series of techniques for modeling, simulation and design of photonic devices and circuits with the emphasis of handling of radiation wave and the related power couplings. The fundamental issue in optical waveguide analysis is to obtain the complete mode spectrum. In principle, we need the radiation modes to expand the arbitrary fields of an open waveguide. In practice, however, the continuum nature of the radiation modes makes them hard to use. The discrete leaky modes may approximately represent a cluster of radiation modes under some circumstance and can be utilized in mode expansion together with guided modes to significantly simplify the analysis of mode coupling problems in optical waveguides. However, the leaky modes are unbounded by nature and hence lack the usual characteristics of normal guided modes in terms of normalization and orthogonality. Recently a novel scheme for handling of radiation optical fields was proposed and demonstrated by applying perfectly matching layers (PML) terminated with a perfectly reflecting boundary (PRB) condition. In this scheme, the radiation fields are represented in terms of a set of complex modes, some of which resemble the conventional leaky modes and others associated with the interaction between the PML media and the reflecting numerical boundaries. The mode spectrum is therefore split into the guided modes and complex modes which possess the normal mode features such as normalization and modal orthogonality. The seemingly paradoxical application of both the PML and PRB in the new method has in fact overcome one of the main challenges assoiated with this traditional method, i.e., the desire for discrete, orthogonal, and normalized modes to represent radiation fields and the need for elimination and reduction of spurious reflections from the edges of the finite computation window. With the understanding of mode spectrum, a full vector mode matching method and a complex coupled mode method for analyzing the wave propagation in optical waveguides under the framework of PRL and PRB computation model have been proposed. The methods have been validated through various structures such as waveguide facet, polarization rotators, long/short period gratings etc. Then the proposed techniques have been utilized to design a series of waveguide structures based on surface plasmonic polaritons, slot waveguides etc. / Thesis / Doctor of Philosophy (PhD)

Modal Methods

Modeling

Simulation

Photonic Devices

Hybrid methods for inverse force estimation in structural dynamics

Sehlstedt, Niklas

January 2003

No description available.

inverse force estimation

dynamic boundary traction vector

hilbert space basis

modal methods

inverse problem

Hybrid methods for inverse force estimation in structural dynamics

Sehlstedt, Niklas

January 2003

No description available.

inverse force estimation

dynamic boundary traction vector

hilbert space basis

modal methods

inverse problem

Identification of Multi-Dimensional Elastic and Dissipation Properties of Elastomeric Vibration Isolators

Ramesh, Ram S.

02 August 2018

No description available.

Mechanical Engineering

Caractérisation de matériaux plasmas pour la conception de fonctions hyperfréquences / Characterization of plasma media for the design of hyperfrequency functions

Chruszez, Olivier

04 February 2015

Afin de mettre à profit les propriétés des plasmas pour développer des fonctions hyperfréquences originales, le milieu plasma doit d’abord être caractérisé dans cette gamme de fréquence car son expansion et sa densité, supposée homogène, sont des paramètres mal maîtrisés. Une méthode de mesure de la constante diélectrique du plasma a donc été développée pour déterminer une permittivité relative complexe moyenne dans les conditions d’utilisation et d’excitation. A partir d’un modèle basé sur une méthode modale, et de la mesure de fréquence de résonance d’un résonateur, on caractérise un milieu plasma (permittivité, fréquence de coupure plasma) généré au sein d’une ligne microruban multicouches. Cette thèse, à l’intersection entre deux disciplines, plasmas et micro-ondes, valide l’utilisation de plasma localisé au sein d’une technologie planaire multicouches pour dimensionner des lignes d’impédance et/ou longueur de ligne variables. Elle met également en avant les difficultés rencontrées en termes de réalisation, pour générer des plasmas reproductibles et stables. / In order to take profits of the plasma properties to develop new hyperfrequency funtioncs, the plasma media must be first characterize in this frequency range because his expansion and density, supposed homogeneous, are parameters not well known. A method of measurement of the plasma’s dielectric constant have been developped to determine an average relative complexe permittivity in the condition of use and excitation. From this method based on a modal method, and from the measurement of the resonant frequency, we can characterize the plasma media (permittivity, cut-off frequency of the plasma) generated within a multilayer microstrip line. This thesis, which verge on the junction between two major fields : microwaves and plasma physics, allowed us to ascertain on the local use of plasma media within multilayer planar technology, in order to design lines with variable impedance and/or variable electrical length. It also highlights on the major difficulties with the generation of stable and reproductible plasma.

Physique des plasmas

Reconfigurabilité

Méthode modale

Filtre

Caractérisation

Micro-ondes

Technologie planaire multicouche

Plasma physics

Reconfigurability

Modal methods

Characterization

Microwave

Multilayer planar technology