Analýza přechodů vedení v pásmech milimetrových vln / Analysis of planar junction in millimeter bands

Ambros, Martin

January 2013

This diploma thesis solves possibilities of transitions between waveguides and hybrid types of integrated microwave circuits. It describes the basic ways of solutions this transitions in both longitudinal and transverse as well. In thesis is also mentioned the principle of SIW technology, which is in this transitions widely used. The practical part is focused on the modeling and analysis of selected structures in CST MW Studio. Modeled structures are optimized for the lowest possible value insertion loss transition and are adapted to the characteristic impedance on 50. Selected structures are recalculated to a lower frequency band, realized and results of their simulation verified by measurements.

Asymptotic Analysis Of The Dispersion Characteristics Of Structural Acoustic Waveguides

Sarkar, Abhijit

06 1900

In this work, we study the coupled dispersion characteristics of three distinct structural-acoustic waveguides, namely: -(1) a two-dimensional waveguide, (2) a fluid-filled circular cylindrical shell and (3)a fluid-filledelliptic cylindrical shell. Our primary interest is in finding coupled wavenumbers as functions of the fluid-structure coupling parameter(µ). Using the asymptotic solution methodology, we find the coupled wavenumbers as perturbations over the uncoupled wavenumbers of the component systems (the structure and the fluid). The asymptotic method provides us with analytical expressions of the coupled wavenumbers for small and large values of µ. The dispersion curves obtained from these extreme values of µ help in predicting the nature of the continuous transition of the wavenumber branches over the entire range of µ. Since the coupled wavenumbers are obtained as perturbations over the uncoupled wavenumbers, the perturbation term characterizes the effect of one medium over the other in terms of additional mass or stiffness. As is common in asymptotic methods, a particular form of the asymptotic expansion remains valid over a certain frequency range only. Hence, different scalings of the asymptotic parameter are used for different frequency ranges. In this regard, the method adopted uses principles of Matched Asymptotic Expansion (MAE). As mentioned above, we begin the study with a two-dimensional structural acoustic waveguide. Depending on the boundary condition at the top-edge of the fluid-layer (rigid or pressure-release), two cases are separately analyzed. In both these cases, only a single perturbation parameter (µ) is used. This is followed by the study of the axisymmetric mode vibration of a fluid-filled circular cylindrical shell. Here, in addition to , we include the Poisson’s ratio as another asymptotic parameter. The next problem studied is the beam mode (n =1)vibration of the same fluid-filled circular cylindrical shell. Here, the frequency is used as an asymptotic parameter (in addition to ) and the derivations proceed in two separate parts, one for the high frequency and the other for the low frequency. Having completed the n = 0 and n = 1 modes of the cylindrical shell, the higher order shell modes are studied using the simpler shallow shell theory. For the final system, viz., the elliptic cylindrical shell, another asymptotic parameter in the form of the eccentricity of the cross-section is used. Having derived the analytical expressions for the coupled wavenumbers and obtained the dispersion curves, a unified behavior of structural-acoustic systems is found to emerge. In all these systems, for small , the coupled wavenumbers are close to the in vacuo structural wavenumber and the wavenumbers of the rigid-walled acoustic duct. The measure of closeness is quantified by . As µ increases, these wavenumber branches get shifted continuously till for large µ, the coupled wavenumber branches are better identified as perturbations to the wavenumbers of the pressure-release acoustic duct. At the coincidence region, the coupled structural wavenumber branch transits to the coupled acoustic wavenumber branchand vice-versa. As a result, at coincidence frequencies, while the uncoupled wavenumber branches intersect, due to the coupling, there is no longer an intersection. These common characteristics are shared amongst all the systems despite the difference in geometries. This suggests that the above discussed features capture the essential physics of sound-structure coupling in waveguides.This workthus presents a novel unified view-point to the topic. Along the way, some additional novel studies are conducted which do contribute to the completeness of the work. The free wavenumbers determined from the asymptotic expressions are usedto calculate the forced response of the two-dimensional waveguide due to a δ forcing. Using this analysis, we are able to come up with a novel explanation of the observation that with coupling the dispersion curves cannot intersect. Additionally, the effect of bulk flow in the acoustic fluid is also comprehensively studied for the easier case of the two-dimensional waveguide. Further, the well-known universal dispersion relation for the higher order circumferential modes of the in vacuo circular cylindrical shell is re-derived using a simpler method.

Acoustic Waveguides

Structural Acoustics

Two-Dimensional Waveguides

Fluid-Filled Cylindrical Shell

Circular-Cylindrical Waveguide

Elliptic-Cylindrical Waveguide

Structural Acoustic Waveguide

FEM/BEM Formulation

Acoustics

Filtr na bázi vlnovodu integrovaného do substrátu / Substrate integrated waveguide filter

Vyskočil, Jiří

January 2011

In this thesis is discussed a filter design of a band-pass substrate integrated waveguide filter on the frequency of 5 GHz. It also includes design theory, filter synthesis, filter analysis in the program CST Microwave Studio® and the results of measurement on a vector network analyzer. The analysis results are compared with the measured results. Good agreement between simulated and measured results is observed.

Design and Fabrication of Suspended Waveguides With Photonic Grating Structures

Lombardo, David

29 June 2020

No description available.

Optics

Engineering

Materials Science

Nanotechnology

nanofabrication

waveguides

photonics,brillouin

SBS

waveguide design

evanescent field sensor

evanescent

fabrication

nano

optical waveguide

optics

suspended waveguide

suspension

MEMS

CMOS

subwavelength

Direct Write of Chalcogenide Glass Integrated Optics Using Electron Beams

Hoffman, Galen Brandt

16 December 2011

No description available.

Optics

integrated optics

photonics

waveguide

waveguide fabrication

electron beam lithography

electron beam

chalcogenide glass

photolithography

germanium selenide

Ge0.2Se0.8

Ge20Se80

bragg grating

bragg mirror

waveguide bragg grating

Analysis and Design of Microwave Reconfigurable Filters in ESIW Technology

Sánchez Marín, Juan Rafael, Juliá Morte, María Trinidad

January 2015

Microwave filters are essential components in high frequency communication systems. The features required for these devices are increasing due to the increase in frequency, caused by the saturation of the electromagnetic spectrum. Among these features, the need for low cost devices with a reduced mass and volume and the need to integrate them with the current planar technology are highlighted. In addition, it is interested to have reconfigurable devices, that is, they can adjust their frequency response, replacing the need of multiple devices. So far, metallic waveguide filters have been used, but lately Substrate Intregated Waveguide (SIW) technology has appeared, and within this family, the innovative Empty Substrate Integrated Waveguide (ESIW). ESIW technology is empty, so that, it can be filled with liquid crystal (LC). The LC is a dielectric material with variable permittivity, which makes the filter can change its center frequency and bandwidth. There are several commercial tools based on numerical methods that enable to carry out the analysis and design of these structures, but they require a very high computational time during the analysis process. This affects negatively the automated design of these structures. On the one hand, an efficient and accurate analysis tool is developed in the thesis by following a strategy that consists on dividing the device under analysis in simple building blocks: waveguides filled with dielectric material, change of medium, discontinuities between guides and dielectric discontinuities. All of them are canonical structures or sufficiently simple that can be analyzed with modal methods. The Generalized Scattering Matrix (GSM) of each block is obtained, and they are linked in cascade by using an efficient technique. The accuracy and effectiveness of this tool are checked using it to analyze multiple filters, comparing the result with a commercial software. Furthermore, an analysis about how the variation of the permittivity of the liquid crystal affects in the frequency response of the filter is made. On the other hand, a tool for designing filters for high frequency communications is developed, in order to integrate it into a Computer Aided Design (CAD) tool. To do this, the classical techniques for designing waveguide filters are followed by adapting them to the new topology under design. Different synthesis and optimization strategies are implemented. These strategies are based on the synthesis of a starting point, the segmentation of the structure under design and the hybridization of different optimization algorithms. Also, a tool for calculating the values ​​of the permittivity of the LC that allows the reconfiguration of the filter is developed. These new permittivities enable to obtain a new desired frequency response. This tool has been used to design various microwave filters on H plane, using ESIW technology filled with liquid crystal. The accuracy and the effectiveness of this tool are checked. In addition, the reconfiguration tool designed is evaluated. Finally, a study of the manufacturing aspects is done, such as how to feed the filter and the solutions to polarize the liquid crystal. Taking into account all these considerations a prototype is manufactured and measured.

Reconfigurable

Microwave

Filters

ESIW

Empty

Substrate

Integrated

Waveguide

L-Band Coplanar Slot Loop Antenna for iNET Applications

Nithianandam, Jeyasingh

10 1900

ITC/USA 2010 Conference Proceedings / The Forty-Sixth Annual International Telemetering Conference and Technical Exhibition / October 25-28, 2010 / Town and Country Resort & Convention Center, San Diego, California / In this article we present a design of an L-band slot loop antenna with a dielectric loaded conductor backed coplanar waveguide (CBCPW) feed. The coplanar slot loop antenna has a transmission line resonator in series. We used full wave electromagnetic simulations with Ansoft's high frequency structure simulator (HFSS) software in the design of the coplanar slot loop antenna. The series transmission line resonator helps to tune the coplanar slot loop antenna and reduce its size. We present here results on return loss and radiations patterns of coplanar slot loop antenna obtained from HFSS simulations.

slot loop

coplanar waveguide

return loss

bandwidth

radiation pattern

Fabrication and Characterization of Superconductive Coplanar Waveguide Resonators : Fabrication and Characterization of Superconductive Coplanar Waveguide Resonators

Ergül, Adem

January 2009

<p>The objective of this thesis is to evaluate a generic process for fabrication and characterization of the Superconductive coplanar waveguide (CPW) resonators. Superconductive CPW resonators with various lengths and shapes are designed to investigate their electrical and magnetic properties as well as resonance properties and sensitivities. In the first part of thesis, two different models are introduced in order to estimate the nonlinear kinetic inductance of a superconducting CPW resonator. The first model is based on Bean critical-state model and the second one is based on current dependence of London penetration depth. The existence of a shift in resonant frequency  of Superconductive CPW resonator caused by a non-linear kinetic inductance is also shown experimentally. Simulations were carried out to estimate the nonlinear kinetic inductance due to the self- induced magnetic field penetration.</p><p>The rest of the thesis is concerned with development of very smooth Aluminum (Al) thin films with RMS (Root Mean Square) roughness 1~nm and CAD (Computer Aid Design) of superconductive CPW resonators. Experimental investigation of a generic fabrication technique for superconductive CPW resonator is carried out. Many resonators are fabricated with different design parameters, such as centerline or gap width, film thickness and gap capacitors length. The fabrication process is described in detail. Electron Beam Lithography is used to fabricate Nb and Al CPW resonators which are coupled to outer conductors via gap capacitors. We have fabricated GHz frequency CPW resonators with quality factors, Q up 5X10^5.</p>

Coplanar

Waveguide

Resonator

Superconductive

Fabrication

Characterization

Superconductivity

Supraledning

Phononic Crystal Waveguiding in GaAs

Azodi Aval, Golnaz

29 November 2013

Compared to the much more common photonic crystals that are used to manipulate light, phononic crystals (PnCs) with inclusions in a lattice can be used to manipulate sound. While trying to propagate in a periodically structured media, acoustic waves may experience geometries in which propagation forward is totally forbidden. Furthermore, defects in the periodicity can be used to confine acoustic waves to follow complicated routes on a wavelength scale. Using advanced fabrication methods, we aim to implement these structures to control surface acoustic wave (SAW) propagation on the piezoelectric surface and eventually interact SAWs with quantum structures. To investigate the interaction of SAWs with periodic elastic structures, SAW interdigital transducers (IDTs) and PnC fabrication procedures were developed. GaAs is chosen as a piezoelectric substrate for SAWs propagation. Lift-off photolithography processes were used to fabricate IDTs with finger widths as low as 1.5 micron. PnCs are periodic structures of shallow air holes created in GaAs substrate by means of a wet-etching process. The PnCs are square lattices with lattice constants of 8 and 4 micron. To predict the behavior of a SAW when interacting with the PnC structures, an FDTD simulator was used to calculate the band structures and SAW wave displacement on the crystal surface. The bandgap (BG) predicted for the 8 micron crystal ranges from 180 MHz to 220 MHz. Simulations show a shift in the BG position for 4 micron crystals ranging from 391 to 439 MHz. Two main waveguide geometries were considered in this work: a simple line waveguide and a funneling entrance line waveguide. Simulations indicated an increase in acoustic power density for the funneling waveguides. Fabricated device evaluated with electrical measurements. In addition, a scanning Sagnac interferometer is used to map the energy density of the SAWs. The Sagnac interferometer is designed to measure the outward displacement of a surface due to the SAW. Interferometric measurements confirmed waveguiding in the modified funnel entrance waveguide embedded in the 4 micron PnC. However, they also revealed strong dissipation of the SAW in the waveguide due to the non-vertical sidewalls resulting from the wet-etch process. / Thesis (Master, Physics, Engineering Physics and Astronomy) -- Queen's University, 2013-11-29 15:53:46.369

Phononic Crystal

Waveguide

Sagnac Interferometry

Surface Acoustic Wave

Harmonic Oscillations in Optical Waveguide Arrays

Wu, Jianxiong

11 December 2013

The analogy of optical system to other physical systems has been attracting much attention over the past decades. In coupled optical lattices, phenomena originated from electronic systems, such as Bloch oscillations, Dynamic localization and Zener tunneling, have been extensively investigated and led to novel research directions and applications. Following this idea, harmonic oscillations are spatially mimicked by the propagation of supermodes in quadratically-coupled waveguide arrays. By analyzing the field envelope with the propagation constants and the superposition of the supermodes, we achieve conjugate-imaging at the half-period plane and self-imaging at the full-period plane, which give rise to the linear switching. Combining the linear switching and the nonlinear light propagation triggered at high power level, we demonstrate the superior performances of nonlinear power switching compared with traditional nonlinear directional couplers. Through the linear and nonlinear observation on AlGaAs waveguide array, we present the first experimental proof of the harmonic oscillations in optical waveguide arrays.

Harmonic Oscillations

Optical Waveguide

AlGaAs

Nonlinear Switching

Linear Switching

0544