Investigations on Online Boundary Variation Techniques for Nearly Constant Switching Frequency Hysteresis Current PWM Controller for Multi-Level Inverter Fed IM Drives

Dey, Anubrata

January 2012

In DC to AC power conversion, voltage source inverters (VSI) based current controllers are usually preferred for today’s high performance AC drive which requires excellent dynamic and steady state performances at different transient and load conditions, with the additional advantages like inherent short circuit and over current protection. Out of different types of current controllers, hysteresis controllers are widely used due to their simplicity and ability to meet the requirements for a high performance AC drives. But the conventional hysteresis controllers suffers from wide variation of PWM switching frequency, overshoot in current errors, sub-harmonic components in the current waveform and non-optimum switching at different operating point of the drive system. To mitigate these problems, particularly to control the switching frequency variation, which is the root cause of all other problems, several methodologies like ramp comparison based controller, predictive current controller, etc. were proposed in the literature. But amplitude and phase offset error in the ramp comparison based controllers and complexities involved in the predictive controllers have limited the use of these controllers. Moreover, these type of controllers, which uses three separate and independently controlled tolerance band (sinusoidal type or adaptive) to control the 3-phase currents, shows limited dynamic responses and they are not simple to implement. To tackle the problem of controlling 3-phase currents simultaneously, space vector based hysteresis current controller is very effective as it combines the current errors of all the three phases as a single entity called current error space vector. It has a single controller’s logic with a hysteresis boundary for controlling this current error space vector. Several papers on space vector based hysteresis controllers for 2-level inverter with constant switching frequency have been published, but the application of the constant switching frequency based hysteresis current controllers for multi¬level inverter fed drive system, has not been addressed properly. Use of multi-level inverter in modern high performance drive for medium and high voltage levels is more prominent because of multi-level’s inherent advantages like good power quality, good electromagnetic compatibility (EMC), better DC link voltage utilization, reduced device voltage rating, so on. Even though some of the earlier works describe three-level space vector based hysteresis current controller techniques, they are specific to the particular level of inverters and does not demonstrate constant switching frequency of operation. This thesis proposes a novel approach where nearly constant switching frequency based hysteresis controller can be implemented for any general n-level inverter and it is also independent of inverter topology. In this work, varying parabolic boundary is used as the hysteresis current error boundary for controlling the current in a multi-level space vector structure. The computation of the parabolic boundary is accomplished offline and all the necessary boundary parameters at different operating points are stored in the look-up tables. The varying parabolic boundary for the multi-level space vector structure depends on the sampled reference phase voltage values which are estimated from stator current error information and then using the equivalent circuit model of induction motors. Here, a mapping technique is adopted to bring down all the three phase references to the inner- most carrier region, which results in mapping any outer triangular structure where tip of the voltage space vector is located, to one of the sectors of the inner most hexagon of the multi-level space vector structure. In this way, the required mapped sector information is easily found out to fix the correct orientation of the parabolic boundary in the space vector plane. This mapping technique simplifies the controller’s logic similar to that of a 2-level inverter. For online identification of the inverter switching voltage vectors constructing the present outer triangle of the multi-level space vector structure, the proposed controller utilizes the sampled phase voltage references. This identification technique is novel and also generic for any n-level inverter structure. This controller is having all the advantages of a space vector based hysteresis current controller and that of a multi-level inverter apart from having a nearly constant switching frequency spectrum similar to that of a voltage controlled space vector PWM (VC-SVPWM). Using the proposed controller, simulation study of a five-level inverter fed induction motor (IM) drive scheme, was carried out using Matlab-Simulink. Simulation study showed that the switching frequency variations in a fundamental cycle and over the entire speed range of the linear modulation region, is similar to that of a VC-SVPWM based multi-level VSI. The proposed hysteresis controller is experimentally verified on a 7.5 kW IM vector control drive fed with a five-level VSI. The proposed current error space vector based hysteresis controller providing nearly constant switching frequency is implemented on a TI TMS320LF2812 DSP and Xilinx XC3S200FT256 FPGA based platform. The three-phase reference currents are generated depending on the frequency command and the controller is tested with the drive for the entire operating speed range of the machine in forward and reverse directions. Steady state and quick transient results of the proposed drive are presented in this thesis. This thesis also proposes another type of hysteresis controller, firstly for 2-level inverter and then for general n-level multi-level inverter, which eliminates the parabolic boundary and replaces it with a boundary which is computed online and does not use any look up table for boundary selection. The current error boundary for the proposed hysteresis controller is computed online in a very simple way, using the information of estimated fundamental stator voltages along α and β axes of space vector plane. The method adopted for the proposed controller to compute the boundary does not involve any complicated computations and it selects the optimal vector for switching when current error space vector crosses the boundary. This way adjacent voltage vector switching similar to VC-SVPWM can be ensured. For 2-level inverter, it precisely determines the sector, in which reference voltage vector is present. In multi-level inverter, this controller also finds out the mapped sector information using the same mapping techniques as explained in the first part of this thesis. In both 2-level and multi-level inverter, the proposed controller does not use any look up table for finding individual voltage vector switching times from the estimated voltage references. These switching times are used for the computation of hysteresis boundary for individual vectors. Thus the hysteresis boundary for individual vectors is exactly calculated and the boundary is similar to that of VC-SVPWM scheme for the respective levels of inverter. In the present scheme, the phase voltage harmonic spectrum is very close to that of a constant switching frequency VC-SVPWM inverter. In this thesis, at first, the proposed on line boundary computation scheme is implemented for a 2-level inverter based controller for the initial study, so that it can be executed as fast as 10 µs in a DSP platform, which is required for accurate current control. Then the same algorithm of 2-level inverter is extended for multi-level inverter with the additional logic for online identification of nearest switching voltage vectors (also used in the parabolic boundary case) for the present sampling interval. Previously mentioned mapping technique for multi-level inverter, is also implemented here to bring down the phase voltage references to the inner-most carrier region to realize the multi-level current control strategy equivalent to that of a 2-level inverter PWM current control. Simulation study to verify the steady state as well as transient performance of the proposed controller for both 2-level as well as five-level VSI fed IM drive is carried out using Simulink tool box of MATLAB Simulation Software. The proposed hysteresis controllers are experimentally verified on a 7.5 kW IM vector control drive fed with a two-level VSI and five-level VSI separately. The proposed current error space vector based hysteresis controller providing nearly constant switching frequency profile for phase voltage is implemented on the TI TMS320LF2812 DSP and Xilinx XC3S200FT256 FPGA based platform. The three-phase reference currents are generated depending on the frequency command and the proposed hysteresis controllers are tested with drive for the entire operating speed range of the machine in forward and reverse directions. Steady state and transient results of the proposed drive are also presented for different operating conditions, through the simulation study followed by experimental verifications. Even though the simulation and experimental verifications are done on a 5-level inverter to explain the proposed hysteresis controller, it can be easily implemented for any general n-level inverter, as described in this thesis.

Boundary Varitions

Hysteresis Current Controllers

Power Width Modulation Controllers

Voltage Source Multilevel Inverters

Induction Motor Drives

Multilevel Inverter Fed Motor Drives

Multilevel Inverters

Inverter Fed Induction Motor Drives

Hysteresis Controller

Hysteresis Current Controller

VSI Fed IM Drive

Voltage Source Inverters (VSI)

Electrical Engineering

Major transformation or slight transformation: that is the question for Controllers.

Karimi Semiromi, Ehsan

January 2018

No description available.

Controllers

Knowledge

Knowledge creating

Automation

Slight transformation

Major transformation

Intelligence.

Business Administration

Företagsekonomi

Vizuální řeč ovladačů a sdělovačů obráběcích strojů v Československu v letech 1947-1990 / Visual Language of Controllers and Communicators of Czechoslovak Machine Tools in 1947-1990

Fridrichová, Eva

Unknown Date

This thesis deals with the development of graphical symbols on the control panels of machine tools made by Czech factories TOS from the years 1947–1990. The aim is description genesis graphics controllers and communicators of machine tools and their inclusion in the context of the development of graphic design. As well as determine the influence of design in area of operational graphics. This area has not yet been subjected to closer examination and in terms of consistency of the historical aspects of the Czech graphic is benefit to the future.

Locomotion in Virtual Reality for Room Scale Tracked Areas

Bozgeyikli, Evren

10 November 2016

In the recent years, virtual reality has been used as an effective tool for a wide range of areas such as training, rehabilitation, education and games. The affordability of the new generation headsets helped this medium to become more widespread. However, in order for virtual reality to become mainstream, more content that is specifically designed for this medium is needed. Since virtual reality is a different technology than the computer systems, different design principles may be required for these content for better user experience. One of the crucial components of virtual reality applications is locomotion, since the viewpoint of the user is very important in immersing the users into virtual reality and locomotion is used for moving the viewpoint of user in virtual environments. Locomotion in virtual reality is expected to have a direct effect on user experience in terms of many elements such as effort, enjoyment, frustration, motion sickness and presence. Up to date, many locomotion techniques for virtual reality have been studied in the literature. However, many of these techniques were evaluated in large tracked areas. Although professional motion tracking systems can track large areas, today’s new generation affordable commercial virtual reality systems can only track room scale environments. This dissertation aims at evaluating different locomotion techniques in room scale tracked areas for neurotypical individuals and individuals with ASD. Several previous studies concurred that virtual reality is an effective medium for the training and rehabilitation of individuals with ASD. However, no previous study evaluated locomotion in virtual reality for this specific population. Thus, this dissertation aims at finding out the suitable virtual reality locomotion techniques for individuals with ASD. With these motivations, in this dissertation, locomotion techniques for room scale virtual reality were evaluated under three experiments: virtual reality for vocational rehabilitation system, evaluation of eight virtual reality locomotion techniques, and point & teleport direction specification experiment. In the first experiment of virtual reality for vocational rehabilitation system, locomotion, interaction, and display components in an immersive virtual reality system for vocational rehabilitation was evaluated by 10 neurotypical individuals and 9 individuals with high functioning ASD. The results indicated that neurotypical individuals favored real walking over walk-in-place; tangible interaction over haptic device, touch & snap and touch screen; and head mounted display over curtain screen. For the participants with high functioning ASD, real walking was favored over walk-in-place; touch screen was favored over haptic device, tangible interaction and touch & snap; and curtain screen was favored over head mounted display. In the second experiment, eight virtual reality locomotion techniques were evaluated in a room scale tracked area (2m by 2m). These eight locomotion techniques were: redirected walking, walk-in-place, stepper machine, point & teleport, joystick, trackball, hand flapping and flying. Among these locomotion techniques, the three were commonly used in virtual reality (redirected walking, walk-in-place and joystick), the two were unexplored –explored previously only by a few related studies (stepper machine and point & teleport), and the three were selected and/or modified for individuals with ASD based on their common characteristics (trackball, hand flapping and flying). These eight techniques were evaluated in an immersive virtual reality test environment. A user study was performed with 16 neurotypical participants and 15 participants with high functioning ASD. The results indicated that for neurotypical individuals, point & teleport, joystick and redirected walking were suitable virtual reality locomotion techniques for room scale tracked areas whereas hand flapping and flying were not suitable. For individuals with high functioning ASD, point & teleport, joystick and walk-in-place were suitable virtual reality locomotion techniques for room scale tracked areas whereas hand flapping and flying were not suitable. Locomotion techniques that are similar to point & teleport have been starting to be used in commercial video games, however were not evaluated in the literature. For this reason, a separate experiment was performed as the third experiment to investigate the effects of an additional direction specification component of point & teleport. Since this direction specification component exerted an additional cognitive load into the use of the same technique, which was recommended to be avoided for individuals with ASD in the literature, it was only evaluated by neurotypical individuals. An immersive virtual maze environment was developed and a user study was performed with 16 neurotypical users. The results indicated that the additional direction specification feature did not improve the user experience.

Redirected Walking

Point and Teleport

Controllers

Walk in Place

Head Mounted Display

Computer Sciences

Modelling and design of the eco-system of causality for real-time systems

Danishvar, Morad

January 2015

The purpose of this research work is to propose an improved method for real-time sensitivity analysis (SA) applicable to large-scale complex systems. Borrowed from the EventTracker principle of the interrelation of causal events, it deploys the Rank Order Clustering (ROC) method to automatically group every relevant system input to parameters that represent the system state (i.e. output). The fundamental principle of event modelling is that the state of a given system is a function of every acquirable piece of knowledge or data (input) of events that occur within the system and its wider operational environment unless proven otherwise. It therefore strives to build the theoretical and practical foundation for the engineering of input data. The event modelling platform proposed attempts to filter unwanted data, and more importantly, include information that was thought to be irrelevant at the outset of the design process. The underpinning logic of the proposed Event Clustering technique (EventiC) is to build causal relationship between the events that trigger the inputs and outputs of the system. EventiC groups inputs with relevant corresponding outputs and measures the impact of each input variable on the output variables in short spans of time (relative real-time). It is believed that this grouping of relevant input-output event data by order of its importance in real-time is the key contribution to knowledge in this subject area. Our motivation is that components of current complex and organised systems are capable of generating and sharing information within their network of interrelated devices and systems. In addition to being an intelligent recorder of events, EventiC could also be a platform for preliminary data and knowledge construction. This improvement in the quality, and at times the quantity of input data, may lead to improved higher level mathematical formalism. It is hoped that better models will translate into superior controls and decision making. It is therefore believed that the projected outcome of this research work can be used to predict, stabilize (control), and optimize (operational research) the work of complex systems in the shortest possible time. For proof of concept, EventiC was designed using the MATLAB package and implemented using real-time data from the monitoring and control system of a typical cement manufacturing plant. The purpose for this deployment was to test and validate the concept, and to demonstrate whether the clusters of input data and their levels of importance against system performance indicators could be approved by industry experts. EventiC was used as an input variable selection tool for improving the existing fuzzy controller of the plant. Finally, EventiC was compared with its predecessor EventTracker using the same case study. The results revealed improvements in both computational efficiency and the quality of input variable selection.

006.2

Control Of Stand-Alone Variable Speed Generation System Using Wound Rotor Induction Machine

Jain, Amit Kumar

12 1900

No description available.

Electric Power Generation

Rotors

Speed Controllers

Speed Generation System

Wound Rotor Induction Machine

Electrical Engineering

Modelagem e otimização de atuadores magnéticos no controle de vibrações / Modeling and optimization of magnetic actuators in control of vibrations

Pilotto, Rafael, 1989-

26 August 2018

Orientador: Katia Lucchesi Cavalca Dedini / Dissertação (mestrado) - Universidade Estadual de Campinas, Faculdade de Engenharia Mecânica / Made available in DSpace on 2018-08-26T17:52:06Z (GMT). No. of bitstreams: 1 Pilotto_Rafael_M.pdf: 4691143 bytes, checksum: 8c6f267d72179ac9f88041489c3da8b5 (MD5) Previous issue date: 2015 / Resumo: O uso de atuadores magnéticos para redução de vibrações visa substituir, em algumas ocasiões, os mancais magnéticos, uma vez que o atuador magnético envolve requisitos de projeto de menor complexidade em sua configuração. O presente trabalho consiste em avaliar como um atuador magnético se comporta ao controlar as vibrações em uma viga flexível de material metálico, bi-engastada, modelada computacionalmente, utilizando o método dos elementos finitos. O atuador magnético é inserido no modelo, utilizando a teoria de eletromagnetismo, assim como os componentes: amplificador de corrente, sensor de posição indutivo e um controlador PID (proporcional-integrador-derivativo). No modelo computacional, o atuador e o sensor de posição são posicionados em diferentes nós, com o propósito de estudar a eficácia do sistema atuador-controlador-sensor em função da sua posição ao longo da viga. Os parâmetros do controlador PID foram obtidos utilizando o método de otimização de Ziegler-Nichols, para as posições observadas do sistema atuador-sensor, e a técnica LPV (Linear Parameter Varying ¿ Variação Linear de Parâmetros) foi então aplicada para o desdobramento desses parâmetros como uma função do comprimento da viga. Para a validação experimental, foram utilizados dois dispositivos para a excitação externa da viga: um equipamento eletromecânico, denominado Shaker, que gerou ondas senoidais nas frequências naturais do sistema, com o propósito de verificar o comportamento do conjunto atuador/controlador em condições críticas, e um martelo de impacto, que excitou a viga através de um impulso único, o qual permitiu obter a dissipação de energia na viga em função do tempo decorrido até o amortecimento completo da resposta transiente. Assim, foram realizadas comparações entre os resultados obtidos a partir do modelo por elementos finitos e as análises realizadas sobre as medições na bancada experimental. Pode-se também observar o comportamento do atuador magnético, no que concerne ao controle de vibrações, em função de seu posicionamento ao longo da viga flexível / Abstract: The use of magnetic actuators for vibration reduction aims to substitute, in some occasions, the magnetic bearings, since the magnetic actuator involves less complex project requirements in its configuration. The present study consists of evaluating how a magnetic actuator behaves while controlling vibration in a flexible metallic beam, modeled using the finite elements method. The magnetic actuator is inserted into the model utilizing electromagnetic theory. Other components are added to the model through the theory of control of mechanical systems, such as: current amplifier, inductive position sensor and a PID controller (Proportional-Integral-Derivative). The actuator and the sensor are placed in different nodes in the computational model, in order to study the effectiveness of the actuator-controller-sensor system depending on its positioning in the beam. The parameters of the PID controller for the entire length of the beam were obtained using the Ziegler-Nichols optimization method for the locations of the beam where the actuator-sensor system was positioned and the LPV (Linear Parameter Varying) technique was applied to the unfolding of these parameters as a function of the beam length. For the experimental validation, two devices were used to act as an external excitation in the beam, an electromechanical equipment called Shaker, which generated sinusoidal waves in the natural frequencies of the system, in order to verify the behavior of the actuator/controller in critical conditions, and a modal hammer that excited the beam through a single impulse, which allowed the energy dissipation to be measured as a function of the time period until the complete damping of the transient response. Thus, the results obtained from the finite elements model were compared with the experimental analysis on the test rig. Moreover, the behavior of the magnetic actuator in vibration control is evaluated regarding its position alongside the flexible beam / Mestrado / Mecanica dos Sólidos e Projeto Mecanico / Mestre em Engenharia Mecânica

Vibração

Controladores PID

Método dos elementos finitos

Vibration

PID controllers

Method of finite elements

Norma IEC61131-3: aspectos históricos, técnicos e um exemplo de aplicação. / IEC61131-3 standard: historical and technical aspects and an application example.

Marcos Roberto Faustino

06 September 2005

Este trabalho traça um panorama dos PLCs e tecnologias associadas em momentos anteriores e posteriores à publicação da norma IEC61131-3 e discute aspectos relativos à sua adoção. A aplicação deste norma pode trazer ganhos de produtividade no projeto e implementação de sistemas de automação industrial. Esta dissertação apresenta o caso do "Projeto de modernização dos navios-varredores da Marinha do Brasil" no qual alguns dos conceitos desta norma foram utilizados com sucesso. Ferramentas e metodologias desenvolvidas para adequar o PLC existente a alguns requisitos da norma são descritas ao longo da dissertação. A operação do novo sistema de varredura pode ser verificada através dos resultados experimentais apresentados. / This work presents an overview of the PLC and associated technologies before and after the publication of the IEC61131-3 standard. Some aspects concerning the adoption of this standard are also discussed. The application of this standard can increase productivity in the design and implementation of industrial automation systems. Some concepts of this standard were applied, succesfully, to the modernization of the Brazilian Navy mine-sweepers. Tools and methods that were required in order to adapt the existing PLC to the IEC standard are described. The operation of the newly developed system can be verified by experimental results.

automação industrial

controladores programáveis

motores elétricos

electric motors

industrial automation

programmable controllers

Design and Real-time Implementation of Model-free Control for Solar Collector

Alharbi, Mohammad

08 1900

This work addresses the design and real-time implementation of adaptive control strategies on the parabolic solar collector to enhance the production efficiency under varying working conditions. For example, the unpredictable variations of the solar irradiance and thermal losses, these factors can be a major problem in the control design. The control objective is to force the outlet temperature of the collector fluid, to track a predefined reference temperature regardless of the environmental changes. In this work, two control strategies have been designed and analyzed. First, an intelligent proportional-integral feedback control, which combines the proportionalintegral feedback control with an ultra-local model is proposed. This strategy uses a transfer function model that has been derived and identified from real-time data and used to test the controller performance. Second, an adaptive nonlinear control using Lyapunov stability theory combined with the phenomenological representation of the system is introduced. This strategy uses a bilinear model derived from the heat transfer equation. Both control strategies showed good performance in the simulations with respect to the convergence time and tracking accuracy. Besides, the conventional proportional-integral controller has been successfully implemented in the real system.

Solar energy

Model-free control

Lyapunov control

Intelligent PID controllers

Parabolic solar collector

Input-output representation

Vizuální řeč ovladačů a sdělovačů obráběcích strojů v Československu z let 1947-1990 / Visual Language of Controllers and Communicators of Czechoslovak Machine Tools in 1947-1990

Fridrichová, Eva

January 2017

This thesis deals with the development of graphical symbols on the control panels of machine tools made by Czech factories TOS from the years 1947–1990. The aim is description genesis graphics controllers and communicators of machine tools and their inclusion in the context of the development of graphic design. As well as determine the influence of design in area of operational graphics. This area has not yet been subjected to closer examination and in terms of consistency of the historical aspects of the Czech graphic is benefit to the future.