On Traveling Wave Solutions of Linear and Nonlinear Wave Models (Seeking Solitary Waves)

Moussa, Mounira

02 June 2023

No description available.

Mathematics

Wave theory

Korteweg-de Vries

Linear and non-linear wave

Klein Gordon equation

Airys wave equation

Solitary traveling wave

Design of a 200Gbps externally modulated laser for opto-electronic integration / Design av en 200 Gbps externmodulerad laser för opto-elektronisk integration

Jiang, Tianyu

January 2022

Segmented traveling wave electro-absorption modulators (TWEAMs) can provide a modulation speed above 100 Gb/s, which is needed in new optical communication networks. In the EU-project TWILIGHT, KTH continues the design work of TWEAMs in the EU-projects IPHOBAC and HECTO with the aim to design a new optical modulator to be integrated with an electronic layer. The structure of the modulator has to be changed in order to make it compatible with the integration technology that will be used in the project. Like in previous projects, the PSPICE software is an important tool for the design work. The past studies left a large amount of different models and test data. This thesis has been focused on studying these models and data to see if they can help the future work in the project. This includes the comparison of the geometrical dimensions, the microwave properties, and the simulation results with the fabricated modulators in the past projects. The electrical parameters are also critical for the design work, especially the capacitance which determines the impedance of the modulator. Since the TWILIGHT project needs a new design of the modulator, the calculation of these parameters will change. This thesis contains a study how this can be done and discusses the parameters for the new TWEAM design. / Segmenterade elektroabsorptionsmodulatorer för vandrande vågor (TWEAMs) kan ge moduleringshastigheter över 100 Gb/s, vilket behövs i nya optiska kommunikationsnätverk. I EU-projektet TWILIGHT fortsätter KTH designarbetet av TWEAMs i EU-projektet IPHOBAC och HECTO med syfte att designa en ny optisk modulator som ska integreras med ett elektronik-lager. Modulatorns struktur måste ändras för att den ska bli kompatibel med integrationstekniken som ska användas i projektet. Precis som i tidigare projekt är PSPICE-mjukvaran ett viktigt verktyg för designarbetet. Den tidigare studierna lämnade en stor mängd olika modeller och testdata. Detta examensarbete har fokuserat på att studera dessa modeller och data för att se om de kan hjälpa det framtida arbetet i projektet. Detta inkluderar jämförelsen av de geometriska dimensionerna, mikrovågsegenskaperna och simuleringsresultaten med de tillverkade modulatorerna i tidigare projekt. De elektriska parametrarna är också kritiska för konstruktionsarbetet, speciellt kapacitansen som bestämmer modulatorns impedans. Eftersom TWILIGHT-projektet har en ny design för modulatorn, ändras beräkningen av dessa parametrar. Detta examensarbete innehåller en studie hur detta kan göras och diskuterar parametrarna för den nya TWEAM-designen.

Optical modulator

Externally modulated laser

Traveling-wave

Electroabsorption

PSPICE

Optisk modulator

externmodulerad laser

Resande-våg

Elektroabsorption

PSPICE

Physical Sciences

Fysik

Coupled Transmission Line Based Slow Wave Structures for Traveling Wave Tubes Applications

Zuboraj, MD R.

January 2016

No description available.

Electrical Engineering

Electromagnetics

Comparison of Natural Frequencies for Detection of Cracked Rotor Wheels

Nicole Kinsey Prieto (13161318)

27 July 2022

<p>  </p> <p>High cycle fatigue, regarding turbine engines, is one of the main causes of rotating component failure. Specifically, the blades of the wheels in the fan, compressor, and turbine sub-assemblies. Traditionally strain gauges are employed as a means of measuring blade vibration during component or full engine development testing. For rotating machinery, strain gauges require the use of a slip ring or a telemetry package. This becomes increasingly complicated as the number of strain gauges increase, thus the need for a more non-intrusive measurement capability for discernment of blade stress responses. Non-Intrusive Stress Measurement Systems (NSMS) allow engineers to detect high cycle fatigue (HCF) issues prior to component failure. It is important for the turbine engine industry to monitor for high cycle fatigue issues to maintain a fleet readiness. When unexpected HCF causes component or system failure the potential consequences are grounded fleets, cancelled flights, monetary loss, and loss of life. Once these issues occur an investigation is initiated and could take a few weeks to several months or more to resolve. This time impacts the engine companies as well as the people dependent upon functional engines. HCF monitoring processes and techniques are crucial to preserving fleet maintenance. One of the ways to prevent premature HCF failure is by detecting cracks in the blades or the wheels of the rotor.</p> <p>It <a href="https://hammer.purdue.edu/account/home#_msocom_1" target="_blank">[NLK1]</a> is the subject of this thesis to determine whether the static deflection of the blade as it rotates will begin to grow independent of rotational changes experienced by the rotor for an internal crack in the wheel as opposed to the blade of a rotor. Should a crack in the wheel occur, the stiffness should decrease, which would manifest when testing the rotor’s natural frequencies as a decrease in the natural frequency compared to an un-cracked rotor. The experiment was conducted using analysis tools for predicting blade natural frequencies of the pre-cracked rotor as well as physical experiments to determine the natural frequencies of the post-cracked rotor. The spin facility set up, data acquisition, data reduction, experiment details and results are provided. Both strain gauges and NSMS techniques were used to measure the natural frequencies of the rotor, and detection of damage while mounted in the spin facility. This research effort concluded it is possible to detect a crack in the wheel of a rotor using the NSMS blade stack capability. It is necessary to have a baseline vibration survey to understand the pre-damaged static deflection of each blade. This research also concluded that a comparison of the pre-cracked and post-cracked natural frequencies manifested roughly a 5% decrease. With a crack in the wheel, the expected stiffness of the wheel would decrease, thus, causing a decrease in the natural frequency of the component. This is evident in the comparison of the pre-cracked ping test data and the post-crack bench test data. In summary, it is possible to detect an internal crack of a rotor and the natural frequencies of the blades can change with an internally cracked wheel. </p>

crack

wheel

rotor

blade

blisk

IBR

detection

natural frequency

frequency

ping test

traveling wave

Theory, Design and Development of Resonance Based Biosensors in Terahertz and Millimeter-wave

Neshat, Mohammad

January 2009

Recent advances in molecular biology and nanotechnology have enabled scientists to study biological systems at molecular and atomic scales. This level of sophistication demands for new technologies to emerge for providing the necessary sensing tools and equipment. Recent studies have shown that terahertz technology can provide revolutionary sensing techniques for organic and non-organic materials with unprecedented accuracy and sensitivity. This is due to the fact that most of the macromolecules have vibrational and/or rotational resonance signatures in terahertz range. To further increase the sensitivity, terahertz radiation is generated and interacted with the bio-sample on a miniaturized test site or the so-called biochip. From the view point of generation and manipulation of terahertz radiation, the biochip is designed based on the same rules as in high frequency electronic chips or integrated circuits (IC). By increasing the frequency toward terahertz range, the conventional IC design methodologies and analysis tools fail to perform accurately. Therefore, development of new design methodologies and analysis tools is of paramount importance for future terahertz integrated circuits (TIC) in general and terahertz biochips in particular. In this thesis, several advancements are made in design methodology, analysis tool and architecture of terahertz and millimeter-wave integrated circuits when used as a biochip. A global and geometry independent approach for design and analysis of the travelling-wave terahertz photomixer sources, as the core component in a TIC, is discussed in details. Three solvers based on photonic, semiconductor and electromagnetic theories are developed and combined as a unified analysis tool. Using the developed terahertz photomixer source, a resonance-based biochip structure is proposed, and its operation principle, based on resonance perturbation method, is explained. A planar metallic resonator acting as a sample holder and transducer is designed, and its performance in terms of sensitivity and selectivity is studied through simulations. The concept of surface impedance for electromagnetic modeling of DNA self-assembled monolayer on a metal surface is proposed, and its effectiveness is discussed based on the available data in the literature. To overcome the loss challenge, Whispering Gallery Mode (WGM) dielectric resonators with high Q factor are studied as an alternative for metallic resonator. The metallic loss becomes very high at terahertz frequencies, and as a result of that planar metallic resonators do not exhibit high Q factor. Reduced Q factor results in a low sensitivity for any sensor using such resonators. Theoretical models for axially and radially layered dielectric resonators acting on WGM are presented, and the analytical results are compared with the measured data. Excitation of WGM through dielectric waveguide is proposed, and the critical coupling condition is explained through analytical formulation. The possibility of selecting one resonance among many for sensing application is also studied both theoretically and experimentally. A high sensitivity sensor based on WGM resonance in mm-wave and terahertz is proposed, and its sensitivity is studied in details. The performance of the proposed sensor is tested for sensing drug tablets and also liquid droplets through various measurements in mm-wave range. The comprehensive sensitivity analysis shows the ability of the proposed sensor to detect small changes in the order of 10−4 in the sample dielectric constant. The results of various experiments carried out on drug tablets are reported to demonstrate the potential multifunctional capabilities of the sensor in moisture sensing, counterfeit drug detection, and contamination screening. The measurement and simulation results obtained in mm-wave hold promise for WGM to be used for sensing biological solutions in terahertz range with very high sensitivity.

Terahertz

Biosensor

Biochip

Traveling-wave

Photomixer

Resonator

Coplanar strip

Sensitivity

Whispering gallery mode

Q factor

Millimeter-wave

Resonance frequency

Electrical and Computer Engineering

Theory, Design and Development of Resonance Based Biosensors in Terahertz and Millimeter-wave

Neshat, Mohammad

January 2009

Recent advances in molecular biology and nanotechnology have enabled scientists to study biological systems at molecular and atomic scales. This level of sophistication demands for new technologies to emerge for providing the necessary sensing tools and equipment. Recent studies have shown that terahertz technology can provide revolutionary sensing techniques for organic and non-organic materials with unprecedented accuracy and sensitivity. This is due to the fact that most of the macromolecules have vibrational and/or rotational resonance signatures in terahertz range. To further increase the sensitivity, terahertz radiation is generated and interacted with the bio-sample on a miniaturized test site or the so-called biochip. From the view point of generation and manipulation of terahertz radiation, the biochip is designed based on the same rules as in high frequency electronic chips or integrated circuits (IC). By increasing the frequency toward terahertz range, the conventional IC design methodologies and analysis tools fail to perform accurately. Therefore, development of new design methodologies and analysis tools is of paramount importance for future terahertz integrated circuits (TIC) in general and terahertz biochips in particular. In this thesis, several advancements are made in design methodology, analysis tool and architecture of terahertz and millimeter-wave integrated circuits when used as a biochip. A global and geometry independent approach for design and analysis of the travelling-wave terahertz photomixer sources, as the core component in a TIC, is discussed in details. Three solvers based on photonic, semiconductor and electromagnetic theories are developed and combined as a unified analysis tool. Using the developed terahertz photomixer source, a resonance-based biochip structure is proposed, and its operation principle, based on resonance perturbation method, is explained. A planar metallic resonator acting as a sample holder and transducer is designed, and its performance in terms of sensitivity and selectivity is studied through simulations. The concept of surface impedance for electromagnetic modeling of DNA self-assembled monolayer on a metal surface is proposed, and its effectiveness is discussed based on the available data in the literature. To overcome the loss challenge, Whispering Gallery Mode (WGM) dielectric resonators with high Q factor are studied as an alternative for metallic resonator. The metallic loss becomes very high at terahertz frequencies, and as a result of that planar metallic resonators do not exhibit high Q factor. Reduced Q factor results in a low sensitivity for any sensor using such resonators. Theoretical models for axially and radially layered dielectric resonators acting on WGM are presented, and the analytical results are compared with the measured data. Excitation of WGM through dielectric waveguide is proposed, and the critical coupling condition is explained through analytical formulation. The possibility of selecting one resonance among many for sensing application is also studied both theoretically and experimentally. A high sensitivity sensor based on WGM resonance in mm-wave and terahertz is proposed, and its sensitivity is studied in details. The performance of the proposed sensor is tested for sensing drug tablets and also liquid droplets through various measurements in mm-wave range. The comprehensive sensitivity analysis shows the ability of the proposed sensor to detect small changes in the order of 10−4 in the sample dielectric constant. The results of various experiments carried out on drug tablets are reported to demonstrate the potential multifunctional capabilities of the sensor in moisture sensing, counterfeit drug detection, and contamination screening. The measurement and simulation results obtained in mm-wave hold promise for WGM to be used for sensing biological solutions in terahertz range with very high sensitivity.

Terahertz

Biosensor

Biochip

Traveling-wave

Photomixer

Resonator

Coplanar strip

Sensitivity

Whispering gallery mode

Q factor

Millimeter-wave

Resonance frequency

Electrical and Computer Engineering

A PLL Design Based on a Standing Wave Resonant Oscillator

Karkala, Vinay

2010 August 1900

In this thesis, we present a new continuously variable high frequency standing wave oscillator and demonstrate its use in generating the phase locked clock signal of a digital IC. The ring based standing wave resonant oscillator is implemented with a plurality of wires connected in a mobius configuration, with a cross coupled inverter pair connected across the wires. The oscillation frequency can be modulated by coarse and fine tuning. Coarse modification is achieved by altering the number of wires in the ring that participate in the oscillation, by driving a digital word to a set of passgates which are connected to each wire in the ring. Fine tuning of the oscillation frequency is achieved by varying the body bias voltage of both the PMOS transistors in the cross coupled inverter pair which sustains the oscillations in the resonant ring. We validated our PLL design in a 90nm process technology. 3D parasitic RLCs for our oscillator ring were extracted with skin effect accounted for. Our PLL provides a frequency locking range from 6 GHz to 9 GHz, with a center frequency of 7.5 GHz. The oscillator alone consumes about 25 mW of power, and the complete PLL consumes a power of 28.5 mW. The observed jitter of the PLL is 2.56 percent. These numbers are significant improvements over the prior art in standing wave based PLLs.

Voltage Controlled Oscillator

VCO

Phase Locked Loop

PLL

Standing Wave Resonant Oscillator

Traveling Wave Resonant Oscillator

Fine Tuning

Coarse Tuning

Transmission line

Parasitic Extraction

Locking Range

Clock distribution

Novel integrated silicon nanophotonic structures using ultra-high Q resonators

Soltani, Mohammad

17 August 2009

Optical traveling-wave resonator architectures have shown promise for the realization of many compact photonic functionalities in different research disciplines. Realizing these resonator structures in high-index contrast silicon enables dense and large scale integration of large arrays of functionalized resonators in a CMOS-compatible technology platform. Based on these motivations, the main focus of this Ph.D. research has been on the device physics, modeling, implementations, and applications of planar ultra-high Q silicon traveling-wave microresonators in a silicon-on-insulator (SOI) platform. Microdisk, microring, and racetrack resonators are the three general traveling-wave resonator architectures of interests that I have investigated in this thesis, with greater emphasis on microdisks. I have developed efficient tools for the accurate modeling of these resonators. The coupling to these resonators has been through a nano-waveguide side coupled to them. For this purpose, I have developed a systematic method for engineering a waveguide-resonator structure for optimum coupling. I have addressed the development of nanofabrication techniques for these resonators with efficient interaction with a nano-waveguide and fully compatible with active electronic integration. The outcome of the theoretical design, fabrication, and characterization of these resonators is a world-record ultra-high Q (3×10[superscript 6]) with optimum waveguide-resonator interaction. I have investigated the scaling of these resonators toward the ultimate miniaturization and its impact on different physical properties of the resonators. As a result of these investigations, I have demonstrated miniaturized Si microdisk resonators with radii of ~ 1.5 micron and Q > 10⁵ with single-mode operation over the entire large free-spectral range. This is the highest Q (~ one order more than that in previously reported data) that has been obtained for a Si microdisk resonator with this size on a SiO₂ substrate. I have employed these resonators for more advanced functionalities such as large-scale integration of resonators for spectroscopic and filtering applications, as well as the design of flat-band coupled-resonator filter structures. By proposing a systematic method of design, I have shown ultra-compact coupled-resonator filters with bandwidths ranging from 0.4 to 1 nm. I have theoretically and experimentally investigated the performance of ultra-high Q resonators at high powers and in the presence of nonlinearities. At high powers, the presence of two-photon absorption, free-carrier generation, and thermo-optic properties of silicon results in a rich dynamic in the response of the resonator. In both theory and experiment, I have predicted and demonstrated self-sustained GHz oscillation on the amplitude of an ultra-high Q resonator pumped with a continuous-wave laser.

Traveling-wave resonators

Nanofabrication

Microresonators

Microdisk

Waveguide

Silicon photonics

Nanophotonics

Coupled-resonators

Microresonators (Optoelectronics)

Optoelectronic devices

Wave guides

Microelectronics

Silicon Electric properties

Approches fréquentielle et temporelle de la dynamique des tubes à onde progressive / Frequency and time domain approaches to the dynamics of traveling wave tubes

Theveny, Stéphane

29 November 2016

Le tube à onde progressive (TOP) est un dispositif où un faisceau d’électrons se déplaçant sur l’axe d’une hélice interagit avec les ondes électromagnétiques propagées par cette hélice. Il est le siège de nombreuses instabilités : des oscillations (génération d’ondes hyperfréquences parasites), mais aussi des instabilités du faisceau qui ont pour conséquence une dissipation parasite due à l'interception du faisceau par l'hélice. L’objectif de cette thèse est de développer une formulation hamiltonienne au problème permettant des modèles approchés plus compacts, plus précis et plus complets. Après l'avoir exposée, nous présentons un schéma numérique contenant notre modèle discret pour la simulation du TOP. Ce modèle discret a été mis au point pour tenir compte des conditions d'adaptation et de changements de géométrie. Le couplage avec les électrons met en jeu des champs de base simples, et le modèle tient compte de la charge d'espace. Différentes méthodes d'intégration numérique sont développées, dont nous comparons l'efficacité. Nous comparons ce modèle discret avec divers modèles d'amplification des ondes à froid, dont le modèle actuellement utilisé chez Thales pour la conception des tubes ({texttt{MVTRAD}}). Nous montrons aussi que les modèles d'amplification des ondes à froid à deux ou trois dimensions comme {texttt{MVTRAD}} ou {texttt{BWIS}} (prenant en compte les ondes inverses) ne respectent pas nécessairement l'équation de Maxwell-Faraday, contrairement au nôtre. Enfin, nous comparons notre modèle discret de circuit et le modèle d'amplification des ondes à froid dans le cas d'un faisceau linéaire. / A traveling-wave tube (TWT) is a device where an electron beam traveling along the axis of a helix interacts with the electromagnetic waves propagated by this helix. It is sensitive to many instabilities : oscillators (generating noise microwave), but also beam instabilities that generate a noise dissipation due to the interception of the beam by the helix. The aim of this thesis is to find a Hamiltonian formulation of the problem to allow more compact, more accurate and more complete approximate models. Having found one, we start to develop a numerical scheme containing our discrete model for the simulation of TOP. This discrete model has been developed to take into account the tapering sections, geometry changes and adaptations. The coupling with electrons involves simple functions of space, and the model takes space charge into account. Different methods of numerical integration are developed, of which we compare the efficiency. We compared the discrete model with various cold waves amplification models, especially with the model currently used at Thales for the design of their tubes ({texttt{MVTRAD}}). Moreover, we showed that two- or three-dimensional cold wave amplification models like {texttt{MVTRAD}} or {texttt{BWIS}} (which takes into account the backward waves) fail to respect the Maxwell-Faraday equation, contrary to ours. Finally we made a comparison between our circuit discrete model and the amplification model of cold waves in the case of a linear beam.

Tube à onde progressive

Simulation numérique

Interaction onde-Particule

Onde inverse

Domaine fréquentiel

Domaine temporel

Traveling-Wave tube

Numerical simulation

Wave-Particle interaction

Backward wave

Frequency domain

Time domain

Experimental and Computational Investigation of a Rotating Bladed Disk under Synchronous and Non-Synchronous Vibration

Kurstak, Eric

13 October 2021

No description available.

Mechanical Engineering

turbomachinery

jet engine

gas turbine

vibration

tip timing

traveling wave excitation

finite element

reduced order model

mistuning

experimental mistuning study

computational simulation

bladed disk

damping