Robust fault tolerant control of induction motor system

Research into fault tolerant control (FTC, a set of techniques that are developed to increase plant availability and reduce the risk of safety hazards) for induction motors is motivated by practical concerns including the need for enhanced reliability, improved maintenance operations and reduced cost. Its aim is to prevent that simple faults develop into serious failure. Although, the subject of induction motor control is well known, the main topics in the literature are concerned with scalar and vector control and structural stability. However, induction machines experience various fault scenarios and to meet the above requirements FTC strategies based on existing or more advanced control methods become desirable. Some earlier studies on FTC have addressed particular problems of 3-phase sensor current/voltage FTC, torque FTC, etc. However, the development of these methods lacks a more general understanding of the overall problem of FTC for an induction motor based on a true fault classification of possible fault types.In order to develop a more general approach to FTC for induction motors, i.e. not just designing specific control approaches for individual induction motor fault scenarios, this thesis has carried out a systematic research on induction motor systems considering the various faults that can typically be present, having either “additive” fault or “multiplicative” effects on the system dynamics, according to whether the faults are sensor or actuator (additive fault) types or component or motor faults (multiplicative fault) types.To achieve the required objectives, an active approach to FTC is used, making use of fault estimation (FE, an approach that determine the magnitude of a fault signal online) and fault compensation. This approach of FTC/FE considers an integration of the electrical and mechanical dynamics, initially using adaptive and/or sliding mode observers, Linear Parameter Varying (LPV, in which nonlinear systems are locally decomposed into several linear systems scheduled by varying parameters) and then using back-stepping control combined with observer/estimation methods for handling certain forms of nonlinearity.In conclusion, the thesis proposed an integrated research of induction motor FTC/FE with the consideration of different types of faults and different types of uncertainties, and validated the approaches through simulations and experiments

Rigid Body Attitude Estimation: An Overview and Comparative Study

The attitude estimation of rigid body systems has attracted the attention of many researchers over the years. The development of efficient estimation algorithms that can accurately estimate the orientation of a rigid body is a crucial step towards a reliable implementation of control schemes for underwater and flying vehicles. The primary focus of this thesis consists in investigating various attitude estimation techniques and their applications. Two major classes are discussed. The first class consists of the earliest static attitude determination techniques relying solely on a set of body vector measurements of known vectors in the inertial frame. The second class consists of dynamic attitude estimation and filtering techniques, relying on body vector measurements as well other measurements, and using the dynamical equations of the system under consideration. Various attitude estimation algorithms, including the latest nonlinear attitude observers, are presented and discussed, providing a survey that covers the evolution and structural differences of these estimation methods. Simulation results have been carried out for a selected number of such attitude estimators. Their performance in the presence of noisy measurements, as well as their advantages and disadvantages are discussed

Development of software sensors for on-line monitoring of bakers yeast fermentation process

Software sensors and bioprocess are well-established research areas which have much to offer each other. Under the perspective of the software sensors area, bioprocess can be considered as a broad application area with a growing number of complex and challenging tasks to be dealt with, whose solutions can contribute to achieving high productivity and high-quality products. Although throughout the past years in the field of software sensors and bioprocess, progress has been quick and with a high degree of success, there is still a lack of inexpensive and reliable sensors for on-line state and parameter estimation. Therefore, the primary objective of this research was to design an inexpensive measurement system for on-line monitoring of ethanol production during the backers yeast cultivation process. The measurement system is based on commercially available metal oxide semiconductor gas sensors. From the bioreactor headspace, samples are pumped past the gas sensors array for 10 s every five minutes and the voltage changes of the sensors are measured. The signals from the gas sensor array showed a high correlation with ethanol concentration during cultivation process. In order to predict ethanol concentrations from the data of the gas sensor array, a principal component regression (PCR) model was developed. For the calibration procedure no off-line sampling was used. Instead, a theoretical model of the process is applied to simulate the ethanol production at any given time. The simulated ethanol concentrations were used as reference data for calibrating the response of the gas sensor array. The obtained results indicate that the model-based calibrated gas sensor array is able to predict ethanol concentrations during the cultivation process with a high accuracy (root mean square error of calibration as well as the percentage error for the validation sets were below 0.2 gL-1 and 7 %, respectively). However the predicted values are only available every five minutes. Therefore, the following plan of the research goal was to implement an estimation method for continues prediction of ethanol as well as glucose, biomass and the growth rates. For this reason, two nonlinear extensions of the Kalman filter namely the extended Kalman filter (EKF) and the unscented Kalman filter (UKF) were implemented separately for state and parameter estimation. Both prediction methods were validated on three different cultivation with variability of the substrate concentrations. The obtained results showed that both estimation algorithms show satisfactory results with respect to estimation of concentrations of substrates 6 and biomass as well as the growth rate parameters during the cultivation. However, despite the easier implementation producer of the UKF, this method shows more accurate prediction results compared to the EKF prediction method. Another focus of this study was to design and implement an on-line monitoring and control system for the volume evaluation of dough pieces during the proofing process of bread making. For this reason, a software sensor based on image processing was designed and implemented for measuring the dough volume. The control system consists of a fuzzy logic controller which takes into account the estimated volume. The controller is designed to maintain the volume of the dough pieces similar to the volume expansion of a dough piece in standard conditions during the proofing process by manipulating the temperature of the proofing chamber. Dough pieces with different amounts of backers yeast added in the ingredients and in different temperature starting states were prepared and proofed with the supervision of the software sensor and the fuzzy controller. The controller was evaluated by means of performance criteria and the final volume of the dough samples. The obtained results indicate that the performance of the system is very satisfactory with respect to volume control and set point deviation of the dough pieces.Softwaresensoren und Bioprozese sind gut etablierte Forschungsgebiete, die sich gegenseitig viel befruchten können. Unter dem Blickwinkel der Softwaresensorik kann der Bioprozess als ein breites Anwendungsgebiet mit einer wachsenden Zahl komplexer und anspruchsvoller Aufgabenstellungen betrachtet werden, deren Lösung zur Erzielung hoher Produktivität und qualitativ hochwertiger Produkte beitragen kann. Obwohl in den letzten Jahren auf dem Gebiet der Softwaresensoren und des Bioprozesses rasch und mit großem Erfolg Untersuchung erzielt wurden, fehlt es immer noch an kostengünstigen und zuverlässigen Sensoren für die Online-Zustands- und Parameterschätzung. Daher war das primäre Ziel dieser Forschung die Entwicklung eines kostengünstigen Messsystems für die Online-Überwachung der Ethanolproduktion während des Kultivierungsprozesses von Backhefe. Das Messsystem basiert auf kommerziell erhältlichen Metalloxid-Halbleiter-Gassensoren. Die Headspace-Proben des Bioreaktors werden alle fünf Minuten für 10 s an der Gassensor-Anordnung vorbeigepumpt und die Spannungsänderungen der Sensoren werden gemessen. Die Signale des Gassensorarrays zeigten eine hohe Korrelation mit der Ethanolkonzentration während des Kultivierungsprozesses. Um die Ethanolkonzentrationen aus den Daten des Gassensorarrays vorherzusagen, wurde ein Hauptkomponenten-Regressionsmodell (PCR) verwendet. Für das Kalibrierungsverfahren ist keine Offline-Probenahme notwendig. Stattdessen wird ein theoretisches Modell des Prozesses genutzt, um die Ethanolproduktion zu jedem beliebigen Zeitpunkt zu simulieren. Die kinetischen Parameter des Modells werden im Rahmen der Kalibration bestimmt. Die simulierten Ethanolkonzentrationen wurden als Referenzdaten für die Kalibrierung des Ansprechverhaltens des Gassensorarrays verwendet. Die erhaltenen Ergebnisse zeigen, dass das modellbasierte kalibrierte Gassensorarray in der Lage ist, die Ethanolkonzentrationen während des Kultivierungsprozesses mit hoher Genauigkeit vorherzusagen (der mittlere quadratische Fehler der Kalibrierung sowie der prozentuale Fehler für die Validierungssätze lagen unter 0,2 gL-1 bzw. 7 %). Die vorhergesagten Werte sind jedoch nur alle fünf Minuten verfügbar. Daher war der folgende Plan der Untersuchung die Implementierung einer Schätzmethode zur kontinuierlichen Vorhersage von Ethanol sowie von Glukose, Biomasse und der Wachstumsrate. Aus diesem Grund wurden zwei nichtlineare Erweiterungen des Kalman Filters, nämlich der erweiterte Kalman Filter (EKF) und der unscented Kalman Filter (UKF), getrennt für die Zustands und Parameterschätzung implementiert. Beide 8 Vorhersagemethoden wurden an drei verschiedenen Kultivierungen mit Variabilität der Start substratkonzentrationen validiert. Die erhaltenen Ergebnisse zeigen, dass beide Schätzungsalgorithmen zufriedenstellende Ergebnisse hinsichtlich der Schätzung der Konzentrationen von Substraten und Biomasse sowie der Parameter der Wachstumsrate während der Kultivierung ermitteln. Trotz der einfacheren Implementierung des UKF zeigt diese Methode jedoch genauere Vorhersageergebnisse im Vergleich zur EKF-Vorhersagemethode. Ein weiterer Schwerpunkt dieser Untersuchung war der Entwurf und die Implementierung eines Online-Überwachungs- und Regelungssystems für die Volumenauswertung von Teigstücken während des Gärprozesses bei der Brotherstellung. Aus diesem Grund wurde ein auf Bildverarbeitung basierendes Überwachungssystem zur Messung der Teigvolumenauswertung entworfen und implementiert. Das Regelsystem besteht aus einem Fuzzy-Logic-Controller, der das gemessene Volumen für die Regelung nutzt. Die Regelung ist so ausgelegt, dass das Volumen der Teiglinge mit Werten des Volumens eines Teiglings unter Standardbedingungen während des Gärprozesses vergleicht und die Temperatur der Gärkammer entsprechend anpasst. Teiglinge mit unterschiedlichen Hefemengen in den Zutaten und verschiedenen Temperaturstartwerten wurden vorbereitet und unter Anwendung des Fuzzy-Reglers gegärt. Der Regler wurde anhand von Leistungskriterien und dem Endvolumen der Teigproben bewertet. Die erhaltenen Ergebnisse zeigen, dass die Leistung des Systems in Bezug auf die Volumenregelung und die Sollwertabweichung der Teigstücke sehr zufriedenstellend ist

Bank of Extended Kalman Filters for Faults Diagnosis in Wind Turbine Doubly Fed Induction Generator

In order to increase the efficiency, to ensure availability and to prevent unexpected failures of the doubly fed induction generator (DFIG), widely used in speed variable wind turbine (SVWT), a model based approach is proposed for diagnosing stator and rotor winding and current sensors faults in the generator. In this study, the Extended Kalman Filter (EKF) is used as state and parameter estimation method for this model based diagnosis approach. The generator windings faults and current instruments defects are modelled, detected and isolated with the use of the faults indicators called residuals, which are obtained based on the EKF observer. The mathematical model of DFIG for both healthy and faulty operating conditions is implemented in Matlab/Simulink software. The obtained simulation results demonstrate the effectiveness of the proposed technique for diagnosis and quantification of the faults under study

Sensors Fault Diagnosis Trends and Applications

Fault diagnosis has always been a concern for industry. In general, diagnosis in complex systems requires the acquisition of information from sensors and the processing and extracting of required features for the classification or identification of faults. Therefore, fault diagnosis of sensors is clearly important as faulty information from a sensor may lead to misleading conclusions about the whole system. As engineering systems grow in size and complexity, it becomes more and more important to diagnose faulty behavior before it can lead to total failure. In the light of above issues, this book is dedicated to trends and applications in modern-sensor fault diagnosis

Optimised configuration of sensors for fault tolerant control of an electro-magnetic suspension system

For any given system the number and location of sensors can affect the closed-loop performance as well as the reliability of the system. Hence, one problem in control system design is the selection of the sensors in some optimum sense that considers both the system performance and reliability. Although some methods have been proposed that deal with some of the aforementioned aspects, in this work, a design framework dealing with both control and reliability aspects is presented. The proposed framework is able to identify the best sensor set for which optimum performance is achieved even under single or multiple sensor failures with minimum sensor redundancy. The proposed systematic framework combines linear quadratic Gaussian control, fault tolerant control and multiobjective optimisation. The efficacy of the proposed framework is shown via appropriate simulations on an electro-magnetic suspension system