Engineering Electromagnetic Wave Properties Using Subwavelength Antennas Structures

Wang, Shiyi

27 May 2015

No description available.

Engineering

Experiments

Electromagnetics

Nanoscience

Nanotechnology

Optics

Subwavelength antennas

vectorial light

meta-surface

nano structures

full wave control

optical needle field

Návrh obvodů pro zpracování biomedicínských signálů v technologii CMOS / Design of circuits suitable for biomedical signal processing in CMOS technology

Korec, Pavol

January 2017

This master’s thesis deals with half-wave and full-wave rectifiers and instrumentation amplifier design in CMOS technology, suitable for biomedical signal processing. Properties of optional solutions are analyzed and appropriate circuits are designed. Their functionality is verified with simulation. Designed circuits are then used to form a circuit converting differential input voltage into rectified output current.

Modelování mozku krysy / Modeling the brain of a rat

Kuřátko, David

January 2018

This master’s thesis deals with creation and modification of several numerical rat’s brain models which are subsequently used in electromagnetic software CST Studio Suite 2014. The first part of the thesis is focused to insertion of exciting source to the model which depends on the used approach. These sources produce signals on the surface of the rat’s brain model which are then analysed. The experimental part of the thesis dealt with three different procedures of cooking agar jelly, which were used for creation of five plate capacitors, which subsequently served for measure electric properties of phantom. The conclusion of this master’s thesis is focused on comparison between results from simulations and experimental parts with a subsequent analysis of the deviations of results and their possible causes.

[pt] MÉTODOS PSEUDO-ANALÍTICOS DE ONDA COMPLETA, VARIACIONAIS E DE PERTURBAÇÃO PARA MODELAGEN DA PROPAGAÇÃO ELETROMAGNÉTICA EM FORMAÇÕES GEOFÍSICAS COMPLEXAS / [en] SOME NOVEL FULL-WAVE, VARIATIONAL, AND PERTURBATIONAL PSEUDO-ANALYTIC METHODS FOR ELECTROMAGNETIC PROPAGATION MODELING IN COMPLEX GEOPHYSICAL FORMATIONS

LISSETH SAAVEDRA PATIÑO

04 January 2021

[pt] Este trabalho apresenta um estudo abrangente sobre novas técnicas para modelagem de sensores eletromagnéticos usados na prospecção de petróleo. Estes sensores normalmente ficam imersos em formações geofísicas complexas (não homogêneas, dissipativas e anisotrópicas) com dimensões e parâmetros constitutivos do meio envolvendo múltiplas escalas, e isso representa um problema desafiador para as técnicas tradicionais de eletromagnetismo computacional. Nossa proposta supera esses problemas e contribui para uma melhor compreensão dos fenômenos eletromagnéticos físicos que ocorrem nessas estruturas. Analisamos o problema de propagação usando: a) uma técnica de onda completa baseada no método de casamento de modos, b) soluções perturbacionais para a equação integral de Fredholm vetorial baseadas na aproximação de Born, e c) métodos variacionais para o cálculo da impedância dos sensores eletromagnéticos de interesse para a exploração geofísica. Nós apresentamos resultados que demostram a capacidade das técnicas introduzidas nesta tese para modelar de forma acurada e eficiente sensores eletromagnéticos de forma mais realista do que as alternativas disponiveis na literatura. O custo computacional dos algoritmos desenvolvidos é relativamente baixo comparado com técnicas puramente numéricas tradicionais (tais como os métodos de elementos e diferenças finitas ou o método dos momentos). / [en] This work presents a comprehensive study on some techniques for modeling electromagnetic sensors used in well prospecting. These sensors are usually immersed in complex geophysical formations (inhomogeneous, dissipative, and anisotropic) with multiscale dimensions and constitutive parameters of the medium abruptly varying, resulting in a challenging problem for conventional computational electromagnetic techniques. Our proposal overcomes these problems and contributes to a better understanding of the physical electromagnetic phenomena that occur in these structures. We analyzed the propagation problem by using: a) a fullwave method based on the mode-matching technique, b) perturbational solutions for solving a Fredholm integral equation on the grounds of the Born approximation, and c) variational methods for calculating the sensor impedance. We present results that demonstrate the ability of the techniques introduced in this dissertation to accurately and efficiently modeling electromagnetic sensors in a more realistic fashion when compared with other methods available in the literature.The computational cost of the numerical algorithms developed in this work is relatively low if compared to that required in traditional techniques (such as finite elements, finite differences, and method of moments).

[pt] ESPALHAMENTO

[pt] TECNICAS DE ONDA COMPLETA

[pt] TECNICAS DE CASAMENTO DE MODOS

[en] SCATTERING

[en] WELL-LOGGING SENSORS

[en] FULL-WAVE TECHNIQUES

[en] BORN-BASED APPROXIMATION

[en] MODE-MATCHING TECHNIQUES

Hybrid Numerical Models for Fast Design of Terahertz Plasmonic Devices

Bhardwaj, Shubhendu

07 December 2017

No description available.

Electrical Engineering

Plasma Physics

Better imaging for landmine detection : an exploration of 3D full-wave inversion for ground-penetrating radar

Watson, Francis Maurice

January 2016

Humanitarian clearance of minefields is most often carried out by hand, conventionally using a a metal detector and a probe. Detection is a very slow process, as every piece of detected metal must treated as if it were a landmine and carefully probed and excavated, while many of them are not. The process can be safely sped up by use of Ground-Penetrating Radar (GPR) to image the subsurface, to verify metal detection results and safely ignore any objects which could not possibly be a landmine. In this thesis, we explore the possibility of using Full Wave Inversion (FWI) to improve GPR imaging for landmine detection. Posing the imaging task as FWI means solving the large-scale, non-linear and ill-posed optimisation problem of determining the physical parameters of the subsurface (such as electrical permittivity) which would best reproduce the data. This thesis begins by giving an overview of all the mathematical and implementational aspects of FWI, so as to provide an informative text for both mathematicians (perhaps already familiar with other inverse problems) wanting to contribute to the mine detection problem, as well as a wider engineering audience (perhaps already working on GPR or mine detection) interested in the mathematical study of inverse problems and FWI.We present the first numerical 3D FWI results for GPR, and consider only surface measurements from small-scale arrays as these are suitable for our application. The FWI problem requires an accurate forward model to simulate GPR data, for which we use a hybrid finite-element boundary-integral solver utilising first order curl-conforming N\'d\'{e}lec (edge) elements. We present a novel `line search' type algorithm which prioritises inversion of some target parameters in a region of interest (ROI), with the update outside of the area defined implicitly as a function of the target parameters. This is particularly applicable to the mine detection problem, in which we wish to know more about some detected metallic objects, but are not interested in the surrounding medium. We may need to resolve the surrounding area though, in order to account for the target being obscured and multiple scattering in a highly cluttered subsurface. We focus particularly on spatial sensitivity of the inverse problem, using both a singular value decomposition to analyse the Jacobian matrix, as well as an asymptotic expansion involving polarization tensors describing the perturbation of electric field due to small objects. The latter allows us to extend the current theory of sensitivity in for acoustic FWI, based on the Born approximation, to better understand how polarization plays a role in the 3D electromagnetic inverse problem. Based on this asymptotic approximation, we derive a novel approximation to the diagonals of the Hessian matrix which can be used to pre-condition the GPR FWI problem.

621.384

Analysis and design of efficient passive components for the millimeter-wave and THz bands

Berenguer Verdú, Antonio José

29 June 2017

This thesis tackles issues of particular interest regarding analysis and design of passive components at the mm-wave and Terahertz (THz) bands. Innovative analysis techniques and modeling of complex structures, design procedures, and practical implementation of advanced passive devices are presented. The first part of the thesis is dedicated to THz passive components. These days, THz technology suffers from the lack of suitable waveguiding structures since both, metals and dielectric, are lossy at THz frequencies. This implies that neither conventional closed metallic structures used at microwave frequencies, nor dielectric waveguides used in the optical regime, are adequate solutions. Among a variety of new proposals, the Single Wire Waveguide (SWW) stands out due to its low attenuation and dispersion. However, this surface waveguide presents difficult excitation and strong radiation on bends. A Dielectric-Coated Single Wire Waveguide (DCSWW) can be used to alleviate these problems, but advantages of the SWW are lost and new problems arise. Until now, literature has not given proper solution to radiation on bends and, on the other hand, rigorous characterization of these waveguides lacks these days. This thesis provides, for the first time, a complete modal analysis of both waveguides, appropriated for THz frequencies. This analysis is later applied to solve the problem of radiation on bends. Several structures and design procedures to alleviate radiation losses are presented and experimentally validated. The second part of the thesis is dedicated to mm-wave passive components. These days, when implementing passive components to operate at such small, millimetric wavelengths, to ensure proper metallic contact and alignment between parts results challenging. In addition, dielectric absorption becomes significant at mm-wave frequencies. Consequently, conventional hollow metallic waveguides and planar transmission lines present high attenuation so that new topologies are being considered. Gap Waveguides (GWs), based on a periodic structure introducing an Electromagnetic Bandgap effect, result very suitable since they do not require metallic contacts and avoid dielectric losses. However, although GWs have great potential, several issues prevent GW technology from becoming consolidated and universally used. On the one hand, the topological complexity of GWs difficulties the design process since full-wave simulations are time-costly and there is a lack of appropriate analysis methods and suitable synthesis procedures. On the other hand, benefits of using GWs instead of conventional structures are required to be more clearly evidenced with high-performance GW components and proper comparatives with conventional structures. This thesis introduces several efficient analysis methods, models, and synthesis techniques that will allow engineers without significant background in GWs to straightforwardly implement GW devices. In addition, several high-performance narrow-band filters operating at Ka-band and V-band, as well as a rigorous comparative with rectangular waveguide topology, are presented. / Esta tesis aborda problemas actuales en el análisis y diseño de componentes pasivos en las bandas de onda milimétrica y Terahercios (THz). Se presentan nuevas técnicas de análisis y modelado de estructuras complejas, procedimientos de diseño, e implementación práctica de dispositivos pasivos avanzados. La primera parte de la tesis se dedica a componentes pasivos de THz. Actualmente no se disponen de guías de onda adecuadas a THz debido a que ambos, metales y dieléctricos, introducen grandes pérdidas. En consecuencia, no es adecuado escalar las estructuras metálicas cerradas usadas en microondas, ni las guías dieléctricas usadas a frecuencias ópticas. Entre un gran número de recientes propuestas, la Single Wire Waveguide (SWW) destaca por su baja atenuación y casi nula dispersión. No obstante, como guía superficial, la SWW presenta difícil excitación y radiación en curvas. El uso de un recubrimiento dieléctrico, creando la Dielecric-Coated Single Wire Waveguide (DCSWW), alivia estos inconvenientes, pero las ventajas anteriores se pierden y nuevos problemas aparecen. Hasta la fecha, no se han encontrado soluciones adecuadas para la radiación en curvas de la SWW. Además, se echa en falta una caracterización rigurosa de ambas guías. Esta tesis presenta, por primera vez, un análisis modal completo de SWW y DCSWW, adecuado a la banda de THz. Este análisis es aplicado posteriormente para evitar el problema de la radiación en curvas. Se presentan y validan experimentalmente diversas estructuras y procedimientos de diseño. La segunda parte de la tesis abarca componentes pasivos de ondas milimétricas. Actualmente, estos componentes sufren una importante degradación de su respuesta debido a que resulta difícil asegurar contacto metálico y alineamiento adecuados para la operación a longitudes de onda tan pequeñas. Además, la absorción dieléctrica incrementa notablemente a estas frecuencias. En consecuencia, tanto guías metálicas huecas como líneas de transmisión planares convencionales presentan gran atenuación, siendo necesario considerar topologías alternativas. Las Gap Waveguides (GWs), basadas en una estructura periódica que introduce un efecto de Electromagnetic Bandgap, resultan muy adecuadas puesto que no requieren contacto entre partes metálicas y evitan las pérdidas en dieléctricos. No obstante, a pesar del potencial de las GWs, varias barreras impiden la consolidación y uso universal de esta tecnología. Por una parte, la compleja topología de las GWs dificulta el proceso de diseño dado que las simulaciones de onda completa consumen mucho tiempo y no existen actualmente métodos de análisis y diseño apropiados. Por otra parte, es necesario evidenciar el beneficio de usar GWs mediante dispositivos GW de altas prestaciones y comparativas adecuadas con estructuras convencionales. Esta tesis presenta diversos métodos de análisis eficientes, modelos, y técnicas de diseño que permitirán la síntesis de dispositivos GW sin necesidad de un conocimiento profundo de esta tecnología. Asimismo, se presentan varios filtros de banda estrecha operando en las bandas Ka y V con altas prestaciones, así como una comparativa rigurosa con la guía rectangular. / Aquesta tesi aborda problemes actuals en relació a l'anàlisi i disseny de components passius en les bandes d'ona mil·limètrica i Terahercis. Es presenten noves tècniques d'anàlisi i modelatge d'estructures complexes, procediments de disseny, i implementació pràctica de dispositius passius avançats. La primera part de la tesi es focalitza en components passius de THz. Actualment no es disposen de guies d'ona adequades a THz causa que tots dos, metalls i dielèctrics, introdueixen grans pèrdues. En conseqüència, no és adequat escalar les estructures metál·liques tancades usades en microones, ni les guies dielèctriques usades a freqüències òptiques. Entre un gran nombre de propostes recents, la Single Wire Waveguide (SWW) destaca per la seua baixa atenuació i quasi nul·la dispersió. No obstant això, com a guia superficial, la SWW presenta difícil excitació i radiació en corbes. L'ús d'un recobriment dielèctric, creant la Dielecric-Coated Single Wire Waveguide (DCSWW), alleuja aquests inconvenients, però els avantatges anteriors es perden i nous problemes apareixen. Fins a la data, no s'han trobat solucions adequades per a la radiació en corbes de la SWW. A més, es troba a faltar una caracterització rigorosa d'ambdues guies. Aquesta tesi presenta, per primera vegada, un anàlisi modal complet de SWW i DCSWW, adequat a la banda de THz. Aquest anàlisi és aplicat posteriorment per evitar el problema de la radiació en corbes. Es presenten i validen experimentalment diverses estructures i procediments de disseny. La segona part de la tesi es centra en components passius d'ones mil·limètriques. Actualment, aquests components pateixen una important degradació de la seua resposta a causa de que resulta difícil assegurar contacte metàl·lic i alineament adequats per a l'operació a longituds d'ona tan menudes. A més, l'absorció dielèctrica incrementa notablement a aquestes freqüències. En conseqüència, tant guies metàl·liques buides com línies de transmissió planars convencionals presenten gran atenuació, sent necessari considerar topologies alternatives. Les Gap Waveguides (GWs), basades en una estructura periòdica que introdueix un efecte de Electromagnetic Bandgap, resulten molt adequades ja que no requereixen contacte entre parts metàl·liques i eviten les pèrdues en dielèctrics. No obstant, tot i el potencial de les GWs, diverses barreres impedixen la consolidació i ús universal d'aquesta tecnologia. D'una banda, la complexa topologia de les GWs dificulta el procés de disseny atés que les simulacions d'ona completa consumeixen molt de temps i no existeixen actualment mètodes d'anàlisi i disseny apropiats. D'altra banda, és necessari evidenciar el benefici d'utilitzar GWs mitjançant dispositius GW d'altes prestacions i comparatives adequades amb estructures convencionals. Aquesta tesi presenta diversos mètodes d'anàlisi eficients, models, i tècniques de disseny que permetran la síntesi de dispositius GW sense necessitat d'un coneixement profund d'aquesta tecnologia. Així mateix, es presenten diversos filtres de banda estreta operant en les bandes Ka i V amb altes prestacions, així com una comparativa rigorosa amb la guia rectangular. / Berenguer Verdú, AJ. (2017). Analysis and design of efficient passive components for the millimeter-wave and THz bands [Tesis doctoral no publicada]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/84004 / TESIS

Terahertz

technology

passive

components

waveguides

filters

W-band

single-wire

wire

two-wires

modal analysis

modes

modelling

electromagnetics

computational

analytical

experimental

radiation

optimization

dielectric

coating

millimeter-wave

applications

Q-band

Ka-band

V-band

state-of-the-art

gap waveguides

groove

ridge

suspended-strip

microstrip

analysis

full-wave

impedance

transmission lines

theory

error analysis

coupled-lines

narrow-band

TRL

calibration

propagation

space mapping

mathematics

surrogate

comparative

TEORIA DE LA SEÑAL Y COMUNICACIONES