Development of Models for Optical Instrument Transformers

January 2010

abstract: Optical Instrument Transformers (OIT) have been developed as an alternative to traditional instrument transformers (IT). The question "Can optical instrument transformers substitute for the traditional transformers?" is the main motivation of this study. Finding the answer for this question and developing complete models are the contributions of this work. Dedicated test facilities are developed so that the steady state and transient performances of analog outputs of a magnetic current transformer (CT) and a magnetic voltage transformer (VT) are compared with that of an optical current transformer (OCT) and an optical voltage transformer (OVT) respectively. Frequency response characteristics of OIT outputs are obtained. Comparison results show that OITs have a specified accuracy of 0.3% in all cases. They are linear, and DC offset does not saturate the systems. The OIT output signal has a 40~60 μs time delay, but this is typically less than the equivalent phase difference permitted by the IEEE and IEC standards for protection applications. Analog outputs have significantly higher bandwidths (adjustable to 20 to 40 kHz) than the IT. The digital output signal bandwidth (2.4 kHz) of an OCT is significantly lower than the analog signal bandwidth (20 kHz) due to the sampling rates involved. The OIT analog outputs may have significant white noise of 6%, but the white noise does not affect accuracy or protection performance. Temperatures up to 50oC do not adversely affect the performance of the OITs. Three types of models are developed for analog outputs: analog, digital, and complete models. Well-known mathematical methods, such as network synthesis and Jones calculus methods are applied. The developed models are compared with experiment results and are verified with simulation programs. Results show less than 1.5% for OCT and 2% for OVT difference and that the developed models can be used for power system simulations and the method used for the development can be used to develop models for all other brands of optical systems. The communication and data transfer between the all-digital protection systems is investigated by developing a test facility for all digital protection systems. Test results show that different manufacturers' relays and transformers based on the IEC standard can serve the power system successfully. / Dissertation/Thesis / Ph.D. Electrical Engineering 2010

Electrical Engineering

current transformers

equivalent circuits

modeling

optical

voltage transformers

Feasability of a laterally emitting thin film electroluminescence device as an application specific integrated display

Rüdiger, Jörg

January 2001

No description available.

621.381045

Modelling a piezoelectric-driven actuator for active flow control

Ring, Emma

January 2014

Flow control is an area of research of particular interest within automotive and aerospace industries since methods used to affect the fluid flow around vehicles can reduce drag and therefore lower their fuel consumption. One of these methods, which has generated a lot of interest in later years, is called active flow control and uses different types of actuators to impact the surrounding flow. In this thesis a model of a piezoelectric actuator for active flow control has been developed using Lumped Element Modelling and equivalent circuits. This approach, together with the chosen software for implementation, Simulink, provides models which are easy to simulate and evaluate. The actuator model has been validated using a novel methodology with sub-models with the purpose of reducing computational costs. The actuator is therefore divided into two submodels,one for structural and one for fluid dynamics, which are validated separately. This enables the use of simple yet accurate FEM and CFD models instead of time consuming FSI software which the complete model requires. The three implemented models have been validated using cases presented in previous studies and data from CFD-simulations. The results show that the decoupled models can be validated separately and its results can be integrated into the complete model, although further tests with a real actuator is needed. In addition to the modelling, a parameter study of the actuator has been performed in order to prepare for prototype design.

Piezoelectric actuator

Lumped Element Modelling

Equivalent circuits

Active Flow Control

Simulink

Characterization of Vertical Interconnects in 3-D Monolithic Microwave Integrated Circuits (3-D MMIC)

Kang, Qinghua (George)

01 July 2003

No description available.

polyimide processing

dielectric constant measurement

conductor loss

via equivalent circuits

interconnects in MMIC

Controlling Semiconductor Optical Amplifiers for Robust Integrated Photonic Signal Processing

Kuntze, Scott Beland

16 July 2009

How can we evaluate and design integrated photonic circuit performance systematically? Can active photonic circuits be controlled for optimized performance? This work uses control theory to analyze, design, and optimize photonic integrated circuits based on versatile semiconductor optical amplifiers (SOAs). Control theory provides a mathematically robust set of tools for system analysis, design, and control. Although control theory is a rich and well-developed field, its application to the analysis and design of photonic circuits is not widespread. Following control theoretic methods already used for fibreline systems we derive three interrelated state-space models: a core photonic model, a photonic model with gain compression, and a equivalent circuit optoelectronic model. We validate each model and calibrate the gain compression model by pump/probe experiments. We then linearize the state-space models to design and analyze SOA controllers. We apply each linearized model to proof-of-concept SOA control applications such as suppressing interchannel crosstalk and regulating output power. We demonstrate the power of linearized state-space models in controller design and stability analysis. To illustrate the importance of using the complete equivalent circuit model in controller design, we demonstrate an intuitive bias-current controller that fails due to the dynamics of the intervening parasitic circuitry of the SOA. We use the linearized state-space models to map a relationship between feedback delay and controller strength for stable operation, and demonstrate that SOAs pose unusual control difficulties due to their ultrafast dynamics. Finally, we leverage the linearized models to design a novel and successful hybrid controller that uses one SOA to control another via feedback (for reliability) and feedforward (for speed) control. The feedback controller takes full advantage of the equivalent circuit modelling by sampling the voltage of the controlled SOA and using the error to drive the bias current of the controller SOA. Filtering in the feedback path is specified by transfer function analysis. The feedforward design uses a novel application of the linearized models to set the controller bias points correctly. The modelling and design framework we develop is entirely general and opens the way to the robust optoelectronic control of integrated photonic circuits.

semiconductor optical amplifiers

optical control

state-space methods

feedback control

feedforward control

integrated photonics

optical crosstalk

equivalent circuits

0544

Controlling Semiconductor Optical Amplifiers for Robust Integrated Photonic Signal Processing

Kuntze, Scott Beland

16 July 2009

How can we evaluate and design integrated photonic circuit performance systematically? Can active photonic circuits be controlled for optimized performance? This work uses control theory to analyze, design, and optimize photonic integrated circuits based on versatile semiconductor optical amplifiers (SOAs). Control theory provides a mathematically robust set of tools for system analysis, design, and control. Although control theory is a rich and well-developed field, its application to the analysis and design of photonic circuits is not widespread. Following control theoretic methods already used for fibreline systems we derive three interrelated state-space models: a core photonic model, a photonic model with gain compression, and a equivalent circuit optoelectronic model. We validate each model and calibrate the gain compression model by pump/probe experiments. We then linearize the state-space models to design and analyze SOA controllers. We apply each linearized model to proof-of-concept SOA control applications such as suppressing interchannel crosstalk and regulating output power. We demonstrate the power of linearized state-space models in controller design and stability analysis. To illustrate the importance of using the complete equivalent circuit model in controller design, we demonstrate an intuitive bias-current controller that fails due to the dynamics of the intervening parasitic circuitry of the SOA. We use the linearized state-space models to map a relationship between feedback delay and controller strength for stable operation, and demonstrate that SOAs pose unusual control difficulties due to their ultrafast dynamics. Finally, we leverage the linearized models to design a novel and successful hybrid controller that uses one SOA to control another via feedback (for reliability) and feedforward (for speed) control. The feedback controller takes full advantage of the equivalent circuit modelling by sampling the voltage of the controlled SOA and using the error to drive the bias current of the controller SOA. Filtering in the feedback path is specified by transfer function analysis. The feedforward design uses a novel application of the linearized models to set the controller bias points correctly. The modelling and design framework we develop is entirely general and opens the way to the robust optoelectronic control of integrated photonic circuits.

semiconductor optical amplifiers

optical control

state-space methods

feedback control

feedforward control

integrated photonics

optical crosstalk

equivalent circuits

0544

Operation of IR-UWB WBAN antennas close to human tissues

Tuovinen, T. (Tommi)

21 October 2014

Abstract In this dissertation, the operation of planar impulse radio (IR) ultra wideband (UWB) antennas is examined for use in wireless body area networks (WBANs). The objective of the thesis is to consider electromagnetic phenomena due to coupling between an antenna and human body tissues and to analyse the challenges of wideband radiators. The aim is to understand the fundamental behaviour of an antenna in a WBAN, focusing on off-body and on-body communications. The thesis premises follow the international WBAN standard 802.15.6-2012 by the Institute of Electrical and Electronics Engineering (IEEE) and the Federal Communications Commission’s (FCC) UWB regulations (3.1–10.6 GHz). In the examinations, the frequency-dependent modelling of human tissues is considered. The impact of the variation of tissue layer thickness on the performance of an antenna is depicted. The demonstration of the impact of antenna input power is given in terms of generation of heat in tissues and specific absorption rate (SAR). In order to theoretically contemplate the effect of reflections due to tissues on antenna patterns, the opportunities to influence polarization with an artificially anisotropic substrate are derived. With the proposed method, not earlier proposed for WBAN antennas, the smooth patterns without pattern minima can be achieved over the FCC UWB bandwidth. In addition, a theoretical two-path model is applied to the estimation of the antenna pattern shape close to tissues. Various antenna parameters are explored as a function of the use distance to tissue surface to demonstrate the behaviour in the vicinity of a body. The size of the reactive near-field is an important factor for the evaluation of satisfactory on-body performance. The proportions of absorption, mismatch and body losses are analysed close to a body. The connection between the complex input impedance and the dimensions of planar antennas is analysed by using lumped-element equivalent circuits. The impact of the actual width and length of the radiator on the impedance behaviour is presented for the first time. In addition, impedance is analysed in terms of capacitance, inductance and resistance within the reactive near-field for the first time. In order to understand the impact of tissues close to the antenna, the parasitic components for the stages in equivalents are proposed. / Tiivistelmä Tässä väitöskirjassa tarkastellaan laajakaistaisten impulssiradioantennien (IR-UWB) toimintaa langattomissa kehoverkoissa (WBAN). Työn tavoitteena on tarkastella antennin ja ihmiskudoksen kytkeytymisestä johtuvia sähkömagneettisia ilmiöitä ja analysoida laajakaistaisen säteilijän haasteet. Päämääränä on ymmärtää antennin suorituskyky kontekstissa ja kohdeympäristöksi on fokusoitu toiminta kehon pinnalla (on-body) ja keholta poispäin seuraavaan liityntäpisteeseen (off-body). Tutkimustyö pohjautuu IEEE802.15.6-2012-standardiin sekä FCC:n UWB -säännöksiin. Väitöstyössä tarkastellaan taajuusriippuvan ihmiskudoksen mallintamista. Ihmiskudoskerrosten paksuuden vaikutusta antennin suorituskykyyn tutkitaan simuloimalla. Lisäksi tarkastellaan antennin syöttötehon vaikutusta kudoksen lämpiämisen ja tehon absorboitumisen näkökulmasta. Kehon aiheuttamien heijastusten vaikutusta säteilykuvioihin tarkastellaan teoreettisesti ja lisäksi esitetään menetelmä vaikuttaa antennin summapolarisaation kautta säteilykuvion muotoon keinotekoisella epäisotrooppisella substraatilla. Ehdotetulla menetelmällä, mitä ei ole aiemmin kirjallisuudessa esitetty kehoantenneille, voidaan minimoida nollakohtia ja saavuttaa tasainen säteilykuvio FCC UWB -taajuuskaistan yli. Kaksitie-mallia sovelletaan säteilykuvion muodon ennustamiseen kehon läheisyydessä. Useita antenniparametreja havainnollistetaan antennin käyttöetäisyyden funktiona ihmiskudoksesta. Antennin reaktiivisen lähikentän koko on tärkeä tekijä kehoantennille riittävän suorituskyvyn saavuttamiseksi. Absorptio-, epäsovitus- ja kehohäviöiden osuudet edelleen eritellään ja analysoidaan työssä. Työssä tutkitaan kompleksisen syöttöimpedanssin ja antennin fyysisten mittojen yhteyttä hyödyntämällä erilliskomponenteilla muodostettuja vastinpiirejä. Ensimmäistä kertaa antennin käytännön leveyden ja pituuden muutos esitetään suhteessa impedanssikäyttäytymiseen. Impedanssin muutos analysoidaan kapasitanssin, induktanssin ja resistanssin funktiona antennin reaktiivisen lähikentän alueella. Jotta kudoksen vaikutus antennin läheisyydessä voitaan ottaa suunnittelussa huomioon, työssä esitetään tarvittavat parasiittiset komponentit vastinkytkentöjen sarja- ja rinnanasteisiin.

anisotropic substrate

body loss

equivalent circuits

planar antenna

wideband antenna

epäisotrooppinen substraatti

kehohäviöt

laajakaistainen antenni

planaarinen antenni

vastinpiirit

Photovoltaic Source Simulators for Solar Power Conditioning Systems: Design Optimization, Modeling, and Control

Koran, Ahmed Mohammed

28 June 2013

This dissertation presents various systematic design techniques for photovoltaic (PV) source simulators to serve as a convenient tool for the dynamic performance evaluation of solar power conditioning systems and their maximum power point tracking algorithms. A well-designed PV source simulator should accurately emulate the static and the dynamic characteristic of actual PV generator. Four major design features should be adopted in any PV source simulator: (i) high power-stage efficiency, (ii) fast transient response-time, (iii) output impedance matching with actual PV generator, and (iv) precise reference generation technique. Throughout this research, two different PV source simulator systems are designed, modeled, and experimentally verified. The design of the first system focuses mainly on creating new reference generation techniques where the PV equivalent circuit is used to precisely generate the current-voltage reference curves. A novel technique is proposed and implemented with analog components to simplify the reference signal generator and to avoid computation time delays in digital controllers. A two-stage LC output filter is implemented with the switching power-stage to push the resonant frequency higher and thus allowing a higher control-loop bandwidth design while keeping the same switching ripple attenuation as in the conventional one-stage LC output filter. With typical control techniques, the output impedance of the proposed simulator did not  match the closed-loop output impedance of actual PV generator due to the double resonant peaks of the two-stage LC output filter. Design procedures for both control and power-stage circuits are explained. Experimental results verify the steady-state and transient performance of the proposed PV source simulator at around 2.7 kW output. The design concept of the first simulator system is enhanced with a new type of PV source simulator that incorporates the advantages of both analog and digital based simulators. This simulator is characterized with high power-stage efficiency and fast transient response-time. The proposed system includes a novel three-phase ac-dc dual boost rectifier cascaded with a three-phase dc-dc interleaved buck converter. The selected power-stage topology is highly reliable and efficient. Moreover, the multi-phase dc-dc converter helps improve system transient response-time though producing low output ripple, which makes it adequate for PV source simulators. The simulator circuitry emulates precisely the static and the dynamic characteristic of actual PV generator under different environmental conditions including different irradiance and temperature levels. Additionally, the system allows for the creation of the partial shading effect on PV characteristic. This dissertation investigates the dynamic performance of commercial and non-commercial solar power conditioning systems using the proposed simulator in steady-state and transient conditions. Closed-loop output impedance of the proposed simulator is verified at different operating conditions. The impedance profile --magnitude and phase- matches the output impedance of actual PV generator closely. Mathematical modeling and experimental validation of the proposed system is thoroughly presented based on a 2.0 kW hardware prototype. The proposed simulator efficiency including the active-front-end rectifier and the converter stages at the maximum power point is 96.4%. / Ph. D.

ac-dc Power Conversion

dc-dc Power Conversion

Maximum Power Point Tracking

Photovoltaic Cells

Photovoltaic Equivalent Circuits

Development of an equivalent circuit of a large power system for real- time security assessment

Wijeweera, Don Gayan Prabath

14 November 2016

More and more system operators are interested in calculating transfer capability in real-time using real-time power flow models generated from the Energy Management System (EMS). However, compared to off-line study models, EMS models usually cover only a limited portion of the interconnected system. In most situations, it is not practical to extend the EMS model to capture the impact of the external systems and therefore using an equivalent network becomes necessary. The development of equivalent circuits to represent external areas was a topic discussed over the last 50 years. Almost all of these methods require impedance information about the external area to develop the equivalent circuit. Unfortunately utilities do not have the external impedance information in the real-time. Therefore, normal industry practice is to use off-line studies to develop an equivalent circuit and use that circuit in the real-time operation without any validation. This can result in errors in the security assessment. Therefore, power industry need a method to develop or validate an equivalent circuit based on the available real-time information. This thesis work is focussed on meeting that industry need. The work on this thesis presents two new methods that can be used to generate an equivalent circuit based on the boundary conditions. This method involves calculating equivalent impedance between two areas based on the boundary stations voltages, voltage angles and power leaving the boundary stations into external areas. This thesis uses power system simulation between two areas to change the system condition to obtain different boundary bus voltages, voltage angles and power injections to generate necessary data. Regression analysis and least square method is then used to generate the equivalent circuit using these data. It is expected that system changes will provide necessary information in the real-time to generate the equivalent circuit. The proposed methodology is validated with modified three area 300 bus system as well as using Manitoba Hydro’s system. Contingency analysis, transfer level calcula-tion and PV curves analysis is used to validate the proposed method. Simulation results show that the proposed method produces adequate accuracy in comparison with detailed off-line system models. The main advantage of the proposed method as compared to other existing meth-ods such as Ward and REI is that the proposed method does not require external imped-ance information to generate the equivalent circuit. The ability to generate reasonably good equivalent circuit only using available boundary information will help utilities to generate or validate the equivalent circuit based on the current system conditions, which will intern help improve the accuracy of the security assessment / February 2017

Equivalent circuits

Power system interconnection

Power system security

Power system simulation

Power system analysis computing

Power system modelling

Phasor measurement units

Modelos de circuitos equivalentes para explicar espectros de impedância de dispositivos de efeito de campo / Use of equivalent circuit models to explain impedance spectra in field-effect devices

Sousa, Marcos Antonio Moura de

17 April 2013

Biossensores que empregam dispositivos de efeitos de campo podem ser obtidos em diversas arquiteturas, incluindo dispositivos Eletrólito-Isolante-Semicondutor (EIS), que são capacitores em que o eletrodo metálico é substituído por um filme e uma solução. Medindo-se a capacitância em função do potencial aplicado, é possível detectar variações de pH oriundas de reações ou interações entre o filme e o analito. Nesta dissertação, sensores foram produzidos com a adsorção de filmes automontados de dendrímero (PAMAM) e nanotubos de carbono (SWNT) num chip. Medidas de espectroscopia de impedância foram realizadas para investigar o crescimento de cada bicamada do filme automontado, e os dados foram analisados com circuitos equivalentes que continham uma capacitância de dupla camada, um elemento de fase constante e uma capacitância para a região de depleção. Para o chip, os melhores ajustes foram obtidos na frequência de 2 kHz, em que a concentração de dopantes foi 6,6x1020 m-3 para o chip com isolante de SiO2 e de 1,1x1021 m-3 para o chip com isolante de SiO2/Ta2O5. O potencial de banda plana foi -0,2 V e -0,06V, respectivamente. Para os chips recobertos com os filmes de PAMAM/SWNT, observamos que a região de depleção é causada pelas cargas positivas do PAMAM. Com relação às implicações para biossensores, verificamos que o desempenho ótimo deve ser obtido com 3 bicamadas de PAMAM/SWNT. Isso pode explicar a observação empírica na literatura de que existe uma espessura ideal dos filmes para um desempenho otimizado. / Biosensors based on field effect devices can be produced with several architectures, including Electrolyte-Insulator-Semiconductor (EIS) devices, which are capacitors where conventional metal electrodes are replaced by a sensing layer and an electrolyte solution. By measuring the capacitance as a function of the bias voltage, it is possible to detect pH changes that may originate from reactions or interactions between the film in the sensing unit and the analyte. In this study sensors were obtained by adsorbing layer-by-layer (LbL) films made with dendrimers (PAMAM) and carbon nanotubes (SWNT) on a semiconductor chip. Impedance spectroscopy measurements were performed to monitor the growth of each bilayer in the LbL film, whose data were analyzed with equivalent circuits containing a double-layer capacitance, a constant phase element and a capacitance for the depletion region. The results for the semiconductor chip could be best fitted for a frequency of 2 kHz, where the doping concentration was 6.6 x1020 m-3 for the insulating SiO2 layer and 1.1 x1021 m-3 for the SiO2/Ta2O5 layer. The flat band voltage was -0.2 V and -0.06 V, respectively. In the analysis of the chip coated with different numbers of PAMAM/SWNT bilayers, we found that the depletion region appears as a contribution from the positive charges in the PAMAM layer. With regard to implications for biosensors, we found that optimized performance should be reached with three PAMAM/SWNT bilayers, which may explain the empirical finding in the literature that an ideal thickness exists for enhanced performance.

Bicamadas de PAMAM/SWNT

Circuitos equivalentes

Dispositivos de efeito de campo

EIS sensors

Equivalent circuits

Espectroscopia de impedância

Field-effect devices

Impedance spectroscopy

PAMAM/SWNT bilayers

Sensores EIS