Дисертації з теми "Digital state controller"

Магістерська дисертація містить описання вдосконаленого методу синтезу регулятора Р.Ізермана. Представлено, класифікації цифрових багатовимірних систем, математичні моделі та приклади використання методів-аналогів, виведення математичної моделі вдосконаленого методу, експериментальні дослідження вдосконаленого методу та його використання для підвищення точності систем керування з неквадратними матрицями.
The master's dissertation contains a description of the improved method of synthesis of the regulator of R. Izerman. Presented classifications of digital multidimensional systems, mathematical models and examples of using analog methods, derivation of a mathematical model of an improved method, experimental studies of an advanced method and its use to improve the accuracy of control systems with non-square matrices.

In this thesis different control methods are applied to the beam and ball system. Test setup for the previous thesis is handled, circuit assemblies and hardware redesigned. As the system is controlled by the control law partitioning method by a computer, discrete time system model is created. The controllability and the observability of the system are analyzed and a nonlinear controller by using control law partitioning in other words computed torque is designed. State feedback control algorithm previously designed is repeated. In case of calculating the non measurable state variables two different reduced order observers are designed for these two different controllers, one for control law partitioning controller and the other for state-feedback controller. Two controller methods designed for the thesis study are tested in the computer environment using modeling and simulation tools (Also a different controller by using sliding mode controller is designed and tested in the computer environment using simulation tools). A controller software program is written for the designed controller algorithms and this software is tested on the test setup. It is observed that the system is stable when we apply either of the control algorithms.

This work consists of the study, design and implementation of DC-DC converters, used in lighting systems based on light emitting diodes (LEDs). Can be powered by an universal AC voltage source or battery, and the current in the LEDs is controlled digitally. The main objective is to present a proposal of new step-up/down converters topologies with full conversion much higher than that of conventional converters. So, is initially presented an overview of solid-state lighting (SSL). Following is presented the study on the dynamic behavior of converters based on modeling by the method of varying state-space average, ending with the design of a digital PI controller. This work resulted in the application for a patent PI-0801425-6 filed with the INPI, which presents a new family of converters with full conversion extremely wide, called cubic converters.
O presente trabalho consiste do estudo, projeto e implementação de conversores CCCC, aplicados em sistemas de iluminação de estado sólido baseado em diodos emissores de luz (LEDs). Podem ser alimentados por uma fonte de tensão alternada universal ou por uma bateria sendo que a corrente nos LEDs é controlada digitalmente. O objetivo principal é apresentar uma proposta de novas topologias de conversores abaixadores/elevadores com faixa de conversão muito maior que a dos conversores convencionais. Portanto, inicialmente é apresentada uma visão geral sobre iluminação de estado sólido (SSL). Na sequência, é apresentado o estudo sobre o comportamento dinâmico dos conversores baseado na modelagem através do método de variáveis de espaço de estados médio, finalizando com o dimensionamento de um controlador PI digital. Este trabalho resultou no pedido de patente de invenção PI-0801425-6 depositado junto ao INPI, o qual apresenta uma nova família de conversores com faixa de conversão extremamente larga, denominados de conversores cúbicos.
Doutor em Ciências

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CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior
Esta dissertação apresenta uma proposta de controle discreto baseado em reali-mentação de estados aplicado à fonte de alimentação das cargas magnéticas do Sirius. A fonte é formada por associações em série e em paralelo de módulos de menor po-tência para que, em conjunto, possam atender às exigências requeridas de tensão e de corrente dos magnetos. Cada módulo é constituído de dois estágios, um de entrada e outro de saída, em que o segundo é o objeto de estudo deste trabalho. O estágio de saída é constituído por um conversor ponte completa associado a um filtro de terceira ordem. Inicialmente é feita a modelagem do estágio de saída e apresentado um modelo apropriado a uma quantidade genérica de módulos associados em série. Em seguida é feita a discretização da planta e o controle em espaço de estados. Para a alocação dos pólos do sistema em malha fechada é utilizado o Regulador Quadrático Linear Digital. Entretanto, quando módulos são associados, aumenta-se consideravelmente a ordem do sistema e torna-se inviável a medição de todos os estados da planta. Então, é proposto um observador ótimo de ordem reduzida para que este seja capaz de fornecer ao con-trolador os estados que não são medidos. A análise de estabilidade permitiu verificar a robustez do controle em conjunto com o observador de estados. Na associação de módulos em paralelo foram consideradas que as correntes da saída de cada módulo são parcelas do estado que corresponde à corrente das cargas magnéticas. Baseado nesta premissa e no controle feito para o arranjo de módulos em série, foi proposta uma estratégia de controle para o arranjo em paralelo. Os resultados em simulação, tanto para a configuração de módulos em série quanto em paralelo, permitem verificar os desempenhos dinâmicos do controlador e observador de estados.
This dissertation presents a proposal of a discrete-time state-feedback control law applied to the Sirius magnetic source power supply. In order to meet the magnets' required voltage and current levels the source is formed by series and parallel associa-tion of modular converters. Each module is made up of two stages, input and output, in which the later is addressed this work. The output stage is constituted by a full bridge converter associated with a third-order filter. Initially a mathematical model is obtained for a single module. This model is later extended to represent the connection of several modules in series. Then the plant is discretized and state feedback law is designed to control the system. The optimal technique Digital Linear Quadratic Regu-lator was used to place the closed-loop poles. However, when modules are associated, due the order of the system it becomes impracticable to measure all the states. Then an optimal reduced order observer is proposed to provide to controller the states that are not measured. An stability analysis is performed in order to verify the controller robustness. For the association of modules in parallel was considered that the output currents of each module are the parcels of the state corresponding to the current of the magnetic loads. Based on this premise and in the previously control design for the series modules association, is proposed a control topology for the parallel arrange-ment. Simulation results were obtained, for the both configuration of modules series and parallel, and the performances of the controller and state-observer were verified.

In order to increase the power density, the discontinuous conducting mode (DCM) and small inductance is adopted for high power bidirectional dc-dc converter. The DCM related current ripple is minimized with multiphase interleaved operation. The turn-off loss caused by the DCM induced high peak current is reduced by snubber capacitor. The energy stored in the capacitor needs to be discharged before device is turned on. A complementary gating signal control scheme is employed to turn on the non-active switch helping discharge the capacitor and diverting the current into the anti-paralleled diode of the active switch. This realizes the zero voltage resonant transition (ZVRT) of main switches. This scheme also eliminates the parasitic ringing in inductor current. This work proposes an inductance and snubber capacitor optimization methodology. The inductor volume index and the inductor valley current are suggested as the optimization method for small volume and the realization of ZVRT. The proposed capacitance optimization method is based on a series of experiments for minimum overall switching loss. According to the suggested design optimization, a high power density hardware prototype is constructed and tested. The experimental results are provided, and the proposed design approach is verified. In this dissertation, a general-purposed power stage model is proposed based on complementary gating signal control scheme and derived with space-state averaging method. The model features a third-order system, from which a second-order model with resistive load on one side can be derived and a first-order model with a voltage source on both sides can be derived. This model sets up a basis for the unified controller design and optimization. The Î -type model of coupled inductor is introduced and simplified to provide a more clearly physical meaning for design and dynamic analysis. These models have been validated by the Simplis ac analysis simulation. For power flow control, a unified controller concept is proposed based on the derived general-purposed power stage model. The proposed unified controller enables smooth bidirectional current flow. Controller is implemented with digital signal processing (DSP) for experimental verification. The inductor current is selected as feedback signal in resistive load, and the output current is selected as feedback signal in battery load. Load step and power flow step control tests are conducted for resistive load and battery load separately. The results indicate that the selected sensing signal can produce an accurate and fast enough feedback signal. Experimental results show that the transition between charging and discharging is very smooth, and there is no overshoot or undershoot transient. It presents a seamless transition for bidirectional current flow. The smooth transition should be attributed to the use of the complementary gating signal control scheme and the proposed unified controller. System simulations are made, and the results are provided. The test results have a good agreement with system simulation results, and the unified controller performs as expected.
Ph. D.

Vodní energie se nyní stala nejlepším zdrojem elektrické energie na zemi. Vyrábí se pomocí energie poskytované pohybem nebo pádem vody. Historie dokazuje, že náklady na tuto elektrickou energii zůstávají konstantní v průběhu celého roku. Vzhledem k mnoha výhodám, většina zemí nyní využívá vodní energie jako hlavní zdroj pro výrobu elektrické energie.Nejdůležitější výhodou je, že vodní energie je zelená energie, což znamená, že žádné vzdušné nebo vodní znečišťující látky nejsou vyráběny, také žádné skleníkové plyny jako oxid uhličitý nejsou vyráběny, což činí tento zdroj energie šetrný k životnímu prostředí. A tak brání nebezpečí globálního oteplování. Použití internetové techniky k ovladání několika vodních elektráren má velmi významné výhody, jako snížení provozních nákladů a flexibilitu uspokojení změny poptávky po energii na straně spotřeby. Také velmi efektivně čelí velkým narušením elektrické sítě, jako je například přidání nebo odebrání velké zátěže, a poruch. Na druhou stranu, systém získávání dat poskytuje velmi užitečné informace pro typické i vědecké analýzy, jako jsou ekonomické náklady, predikce poruchy systémů, predikce poptávky, plány údržby, systémů pro podporu rozhodování a mnoho dalších výhod. Tato práce popisuje všeobecný model, který může být použit k simulaci pro sběr dat a kontrolní systémy pro vodní elektrárny v prostředí Matlab / Simulink a TrueTime Simulink knihovnu. Uvažovaná elektrárna sestává z vodní turbíny připojené k synchronnímu generátoru s budicí soustavou, generátor je připojen k veřejné elektrické síti. Simulací vodní turbíny a synchronního generátoru lze provést pomocí různých simulačních nástrojů. V této práci je upřednostňován SIMULINK / MATLAB před jinými nástroji k modelování dynamik vodní turbíny a synchronního stroje. Program s prostředím MATLAB SIMULINK využívá k řešení schematický model vodní elektrárny sestavený ze základních funkčních bloků. Tento přístup je pedagogicky lepší než komplikované kódy jiných softwarových programů. Knihovna programu Simulink obsahuje funkční bloky, které mohou být spojovány, upravovány a modelovány. K vytvoření a simulování internetových a Real Time systémů je možné použít bud‘ knihovnu simulinku Real-Time nebo TRUETIME, v práci byla použita knihovna TRUETIME.

This master´s thesis deals with the design of the control circuits for digital potentiometers and their application in analog systems. Digital potentiometers are three-terminal resistors with an adjustable center connection. The digital potentiomneters enable to drive logic gates, LED drivers, LCD drivers, analog switches etc. Controlling of these mentioned devices is possible by the I2C 2- wire serial bus (invented by Philips). The digital potentiometers are used to control of the primary parameters like cut-off frequency and quality factor in the state variable filter and cut-off frequency in a passive filter. Both filters are simulated in PSpice and then compared with the measured results. Next parts of this master's thesis are a computer program and a exemplary protocol.

To support the increasingly demanding requirements for power conversion units, a digitally controlled dual output stage buck converter is designed. The system consists of a dual output stage, which includes an auxiliary buck output stage connected in parallel with a main output stage. The auxiliary output stage is only active during load transient to suppress the output voltage variation. A digital controller is designed to control both stages with a linear/nonlinear control scheme. Nonlinear control is applied during load transient based on the capacitor charge balance principle; whereas linear PID control governs the steady state operation. The design is verified with simulation and experimentally with discrete components. The controller is realized with a FPGA with preset output stage parameters. The experimental result shows a 60% reduction of output voltage variation for a heavy-to-light load transient.

碩士
國立臺灣科技大學
電機工程系
100
High-brightness LEDs are energy-saving and cost-effective choices that enable the next generation of lighting applications. Typically, an LED driver with active PFC is implemented with two-stage topology. The first stage can achieve a near unity power factor and a low THD at universal input voltage range, while the second stage is used for the dc/dc conversion. However, two-stage topology has two independent feedback controls and a high component count, leading to an increased cost and size. In low-power lighting applications, where cost is the dominant issue, such an approach loses attractiveness. On the other hand, digital power control techniques are rapidly gaining market share as designers increasingly appreciate the advantages that the technology offers over its analog counterpart. In this thesis, the digital control technology for single-stage flyback power factor corrector (PFC) is investigated. Firstly, one analog single-stage flyback PFC circuits is built using the L6561 PWM control IC. Next, using the same power stage, two digital control algorithms using the Microchip dsPIC33FJ16GS502 digital signal controller (DSC) are developed. The developed digital control algorithms include digital voltage follower control and digital critical conduction mode control. Finally, experimental results of these three single-stage flyback PFC circuits will be provided to validate the correctness of the proposed digital control algorithms. According to the experimental results, all the three presented PFC circuits can achieve efficiency higher than 85% and power factor higher than 90.

碩士
國立臺灣科技大學
電機工程系
95
The thesis proposes the design and implementation of a fully digitally controlled full-bridge converter with power factor correction. The converter includes two major parts: a power factor correction circuit and a full bridge DC/DC converter. The zero switching technique is used to reduce the switching loss of the DC/DC converter. In addition, a single-stage power factor correction circuit is implemented to improve the power factor in the input AC source. The detailed discussion and analysis are included. An adjustable dead-time control method is proposed here. A 768W, 48V converter has been implemented. All the control algorithms are implemented by a digital signal processor. The experimental results validate the correctness of the proposed circuit, which has good performance and meets the PFC standards.

Desire for low-power, high performance computing has been at core of the symbiotic union between digital circuits and CMOS scaling. While digital circuit performance improves with device scaling, analog circuits have not gained these benefits. As a result, it has become necessary to leverage increased digital circuit performance to mitigate analog circuit deficiencies in nanometer scale CMOS in order to realize world class analog solutions. In this thesis, both circuit and system enhancement techniques to improve performance of clock generators are discussed. The following techniques were developed: (1) A digital PLL that employs an adaptive and highly efficient way to cancel the effect of supply noise, (2) a supply regulated DPLL that uses low power regulator and improves supply noise rejection, (3) a digital multiplying DLL that obviates the need for high-resolution TDC while achieving sub-picosecond jitter and excellent supply noise immunity, and (4) a high resolution TDC based on a switched ring oscillator, are presented. Measured results obtained from the prototype chips are presented to illustrate the proposed design techniques.
Graduation date: 2013
Access restricted to the OSU Community at author's request from July 16, 2012 - July 16, 2014