Active Vibration Control of Multibody Systems : Application to Automotive Design

Olsson, Claes

January 2005

<p>Active vibration control to reduce vibrations and structure borne noise is considered using a powerful multi-disciplinary virtual design environment which enables control system design to be considered as an integral part of the overall vehicle design.</p><p>The main application studied is active automotive engine vibration isolation where, first, the potential of large frequency band multi-input multi-output H₂ feedback control is considered. Facilitated by the virtual environment, it is found necessary to take non-linear characteristics into account to achieve closed-loop stability.</p><p>A physical explanation to why receiver structure flexibility insignificantly affect the open and closed-loop characteristics in case of total force feedback in contrast to acceleration feedback is then given. In this context, the inherent differences between model order reduction by modal and by balanced truncation are being stressed.</p><p>Next, applying state-of-the-art algorithms for recursive parameter estimation, time-domain adaptive filtering is shown to lack sufficient tracking performance to deal with multiple spectral components of transient engine excitations corresponding to rapid car accelerations.</p><p>Finally, plant non-linearity as well as transient excitation are successfully handled using narrow band control based on feedback of disturbance states estimates. To deal with the non-linear characteristics, an approach to generate linear parameter varying descriptions of non-linear systems is proposed. Parameter dependent quadratic stability is assessed using a derived affine closed-loop system representation.</p><p>This thesis also considers actuator saturation induced limit cycles for observer-based state feedback control systems encountered when dealing with the active isolation application. It is stressed that the fundamental observer-based anti-windup technique could imply severely deteriorated closed-loop characteristics and even sustained oscillations. That is in the case when the observer is fed by the saturated control signal in contrast to the computed one. Based on piecewise affine system descriptions, analytical tools to conclude about limit cycles and exponential closed-loop stability are provided for the two observer implementations.</p>

Reglerteknik

Active Vibration Control

Vibration Isolation

Feedback Control

Adaptive Filtering

Saturation

Limit Cycles

Multi Body Systems

Modelling

Simulation

Non-linearity

Gain Scheduling

Structure Flexibility

Reglerteknik

Automatic control

Reglerteknik

Active Vibration Control of Multibody Systems : Application to Automotive Design

Olsson, Claes

January 2005

Active vibration control to reduce vibrations and structure borne noise is considered using a powerful multi-disciplinary virtual design environment which enables control system design to be considered as an integral part of the overall vehicle design. The main application studied is active automotive engine vibration isolation where, first, the potential of large frequency band multi-input multi-output H2 feedback control is considered. Facilitated by the virtual environment, it is found necessary to take non-linear characteristics into account to achieve closed-loop stability. A physical explanation to why receiver structure flexibility insignificantly affect the open and closed-loop characteristics in case of total force feedback in contrast to acceleration feedback is then given. In this context, the inherent differences between model order reduction by modal and by balanced truncation are being stressed. Next, applying state-of-the-art algorithms for recursive parameter estimation, time-domain adaptive filtering is shown to lack sufficient tracking performance to deal with multiple spectral components of transient engine excitations corresponding to rapid car accelerations. Finally, plant non-linearity as well as transient excitation are successfully handled using narrow band control based on feedback of disturbance states estimates. To deal with the non-linear characteristics, an approach to generate linear parameter varying descriptions of non-linear systems is proposed. Parameter dependent quadratic stability is assessed using a derived affine closed-loop system representation. This thesis also considers actuator saturation induced limit cycles for observer-based state feedback control systems encountered when dealing with the active isolation application. It is stressed that the fundamental observer-based anti-windup technique could imply severely deteriorated closed-loop characteristics and even sustained oscillations. That is in the case when the observer is fed by the saturated control signal in contrast to the computed one. Based on piecewise affine system descriptions, analytical tools to conclude about limit cycles and exponential closed-loop stability are provided for the two observer implementations.

Active Vibration Control

Vibration Isolation

Feedback Control

Adaptive Filtering

Saturation

Limit Cycles

Multi Body Systems

Modelling

Simulation

Non-linearity

Gain Scheduling

Structure Flexibility

Automatic control

Reglerteknik

Implementation of adaptive digital FIR and reprogrammable mixed-signal filters using distributed arithmetic

Huang, Walter

12 November 2009

When computational resources are limited, especially multipliers, distributed arithmetic (DA) is used in lieu of the typical multiplier-based filtering structures. However, DA is not well suited for adaptive applications. The bottleneck is updating the memory table. Several attempts have been done to accelerate updating the memory, but at the expense of additional memory usage and of convergence speed. To develop an adaptive DA filter with an uncompromised convergence rate, the memory table must be fully updated. In this research, an efficient method for fully updating a DA memory table is proposed. The proposed update method is based on exploiting the temporal locality of the stored data and subexpression sharing. The proposed update method reduces the computational workload and requires no additional memory resources. DA using the proposed update method is called conjugate distributed arithmetic. Filters can also be constructed from analog components. Often, for lower precision computations, analog circuits use less power and less chip area than their digital counterparts. However, digital components are often used because of their ease of reprogrammability. Achieving such reprogrammability in analog is possible, but at the expense of additional chip area. A reprogrammable mixed-signal DA finite impulse response (FIR) filter is proposed to address the issues with reprogrammable analog FIR filters that are constructing compact reprogrammable filtering structures, non-symmetric and imprecise filter coefficients, inconsistent sampling of the input data, and input sample data corruption. These issues are successfully addressed using distributed arithmetic, digital registers, and epots. Also, a mixed-signal DA second-order section (SOS), which is used as the building block for higher order infinite impulse response filters, was proposed. The type of issues with an analog SOS filter are similar to those of an analog FIR filter, which are the lack of a compact reprogrammable filtering structure, the imprecise filter coefficients, the inconsistent sampling of the data, and the corruption of the data samples. These issues are successfully addressed using distributed arithmetic and digital registers.

Mixed-signal implementations

Reprogrammable

Distributed arithmetic

Adaptive filtering implementations

Adaptive filters

Adaptive signal processing

Computer arithmetic and logic units

Computer algorithms

Digital approach for the design of statistical analog data acquisition on SoCs

Souza Junior, Adao Antonio de

January 2005

With the current demand for mixed-signal SoCs, an increasing number of designers are looking for ADC architectures that can be easily implemented over digital substrates. Since ADC performance is strongly dependent upon physical and electrical features, it gets more difficult for them to benefit from more recent technologies, where these features are more variable. This way, analog signal acquisition is not allowed to follow an evolutionary trend compatible with Moore’s Law. In fact, such trend shall get worst, since newer technologies are expected to have more variable characteristics. Also, for a matter of economy of scale, many times a mixed-signal SoC presents a good amount of idle processing power. In such systems it is advantageous to employ more costly digital signal processing provided that it allows a reduction in the analog area demanded or the use of less expensive analog blocks, able to cope with process variations and uncertainty. Besides the technological concerns, other factors that impact the cost of the design also advise to transfer problems from the analog to the digital domain whenever possible: design automation and self-test requirements, for instance. Recent surveys indicate that the total cost in designer hours for the analog blocks of a mixed-signal system can be up to three times the cost of the digital ones. This manuscript explores the concept of bottom-up analog acquisition design, using statistical sampling as a way to reduce the analog area demanded in the design of ADCs within mixed-signal systems. More particularly, it investigates the possibility of using digital modeling and digital compensation of non-idealities to ease the design of ADCs. The work is developed around three axes: the definition of target applications, the development of digital compensation algorithms and the exploration of architectural possibilities. New methods and architectures are defined and validated. The main notions behind the proposal are analyzed and it is shown that the approach is feasible, opening new paths of future research. Keywords:

Microeletrônica

Conversor analogico/digital

SoC

Sensores

ADC

Stochastic quantization

Mixed-signal systems

Design space exploration

Adaptive filtering

Analog test

Fault tolerance

Filtragem adaptativa híbrida analógico-digital para melhoria na detecção de barras quebradas em motores de indução

Costa, Felipe Sadami Oiwa da

January 2017

Orientador: Prof. Dr. Luiz Alberto Luz de Almeida / Dissertação (mestrado) - Universidade Federal do ABC, Programa de Pós-Graduação em Engenharia Elétrica, 2017. / O motor de indução é a máquina elétrica de maior utilização em todo o planeta e seu desempenho é fundamental nos processos produtivos, fazendo se necessário o funcionamento livre de falhas. Baseado na análise da assinatura da corrente do motor (MCSA) é possível apontar falhas em motores de indução, como barras quebradas, através da análise de variações na corrente do estator, que no domínio da frequência geram bandas laterais à frequência fundamental. Porém, devido à dificuldade e alta complexidade para se lidar com a grande diferença entre as magnitudes das bandas laterais e a frequência fundamental, foi proposto na literatura uma técnica que atenua a componente da frequência fundamental via Transformada Recursiva Discreta de Fourier (RDFT) com objetivo de amplificar os espectros de bandas laterais gerados. Entretanto, a técnica proposta estima a componente fundamental baseando-se em uma frequência fixa (60Hz), sem considerar as oscilações presentes na rede que podem diretamente afetar o resultado da atenuação. É proposto neste trabalho uma filtragem adaptativa híbrida analógico-digital para melhoria na atenuação da componente fundamental através da implementação de um sistema compensador das oscilações da rede composto por um estimador de frequência do tipo "Zero-Crossing" e um oscilador controlado numericamente (NCO). Isto acarreta em baixa complexidade, aumentando a eficiência e confiabilidade do controle dos dados e acima de tudo levando em conta o contexto atual de redução de custos, permite a portabilidade para sistemas de baixo custo e Iot. / The induction motor is the most applied electrical machine around the planet and in its majority, plays a fundamental role in the productive process, requiring faults free functioning. Based on motor current signature analysis (MCSA) it is possible point faults in induction motors, as broken bars, through the analysis of the stators current imbalances, which in frequency domain generate sidebands around the fundamental frequency. Nevertheless, due the difficulty and the high complexity to handle the differences between the sidebands and fundamental frequency magnitudes, a technique which suppresses the fundamental frequency via Recursive Discrete Fourier Transform was proposed in order to amplify the sidebands spectrum generated. However, the proposed technique estimates the fundamental component based on a fixed frequency (60Hz), without considering the grid oscillations which can directly affect the result of the fundamental attenuation. It is proposed in this study a hybrid analogic-digital adaptive filtering in order to improve the fundamental component cancelling technique by implementing a grid oscillations compensator system composed by a Zero-Crossing Frequency Estimator and a Numerically Controlled Oscillator (NCO). It will result in low complexity, increasing the data control efficiency and reliability and above all taking in consideration the current reduction cost context, allow the portability to low cost and Iot systems.

FILTRAGEM ADAPTATIVA

TRANSFORMADA DE FOURIER

ADAPTIVE FILTERING

Digital approach for the design of statistical analog data acquisition on SoCs

Souza Junior, Adao Antonio de

January 2005

With the current demand for mixed-signal SoCs, an increasing number of designers are looking for ADC architectures that can be easily implemented over digital substrates. Since ADC performance is strongly dependent upon physical and electrical features, it gets more difficult for them to benefit from more recent technologies, where these features are more variable. This way, analog signal acquisition is not allowed to follow an evolutionary trend compatible with Moore’s Law. In fact, such trend shall get worst, since newer technologies are expected to have more variable characteristics. Also, for a matter of economy of scale, many times a mixed-signal SoC presents a good amount of idle processing power. In such systems it is advantageous to employ more costly digital signal processing provided that it allows a reduction in the analog area demanded or the use of less expensive analog blocks, able to cope with process variations and uncertainty. Besides the technological concerns, other factors that impact the cost of the design also advise to transfer problems from the analog to the digital domain whenever possible: design automation and self-test requirements, for instance. Recent surveys indicate that the total cost in designer hours for the analog blocks of a mixed-signal system can be up to three times the cost of the digital ones. This manuscript explores the concept of bottom-up analog acquisition design, using statistical sampling as a way to reduce the analog area demanded in the design of ADCs within mixed-signal systems. More particularly, it investigates the possibility of using digital modeling and digital compensation of non-idealities to ease the design of ADCs. The work is developed around three axes: the definition of target applications, the development of digital compensation algorithms and the exploration of architectural possibilities. New methods and architectures are defined and validated. The main notions behind the proposal are analyzed and it is shown that the approach is feasible, opening new paths of future research. Keywords:

Microeletrônica

Conversor analogico/digital

SoC

Sensores

ADC

Stochastic quantization

Mixed-signal systems

Design space exploration

Adaptive filtering

Analog test

Fault tolerance

Digital approach for the design of statistical analog data acquisition on SoCs

Souza Junior, Adao Antonio de

January 2005

With the current demand for mixed-signal SoCs, an increasing number of designers are looking for ADC architectures that can be easily implemented over digital substrates. Since ADC performance is strongly dependent upon physical and electrical features, it gets more difficult for them to benefit from more recent technologies, where these features are more variable. This way, analog signal acquisition is not allowed to follow an evolutionary trend compatible with Moore’s Law. In fact, such trend shall get worst, since newer technologies are expected to have more variable characteristics. Also, for a matter of economy of scale, many times a mixed-signal SoC presents a good amount of idle processing power. In such systems it is advantageous to employ more costly digital signal processing provided that it allows a reduction in the analog area demanded or the use of less expensive analog blocks, able to cope with process variations and uncertainty. Besides the technological concerns, other factors that impact the cost of the design also advise to transfer problems from the analog to the digital domain whenever possible: design automation and self-test requirements, for instance. Recent surveys indicate that the total cost in designer hours for the analog blocks of a mixed-signal system can be up to three times the cost of the digital ones. This manuscript explores the concept of bottom-up analog acquisition design, using statistical sampling as a way to reduce the analog area demanded in the design of ADCs within mixed-signal systems. More particularly, it investigates the possibility of using digital modeling and digital compensation of non-idealities to ease the design of ADCs. The work is developed around three axes: the definition of target applications, the development of digital compensation algorithms and the exploration of architectural possibilities. New methods and architectures are defined and validated. The main notions behind the proposal are analyzed and it is shown that the approach is feasible, opening new paths of future research. Keywords:

Microeletrônica

Conversor analogico/digital

SoC

Sensores

ADC

Stochastic quantization

Mixed-signal systems

Design space exploration

Adaptive filtering

Analog test

Fault tolerance

ESTUDO E DESENVOLVIMENTO DE UMA FAMILIA DE ALGORITMOS NÃO LINEARES PARA FILTRAGEM ADAPTATIVA / STUDY AND DEVELOPMENT DE UMA FAMILY OF Not LINEAR ALGORITHMS FOR FILTERING ADAPTATIVE

Santana, Ewaldo Eder Carvalho

17 February 2006

Made available in DSpace on 2016-08-17T14:52:50Z (GMT). No. of bitstreams: 1 Ewaldo Eder.pdf: 1808292 bytes, checksum: 65e8f3c3afbcf9e5bfd61e1b73fb305f (MD5) Previous issue date: 2006-02-17 / In this work we develop a family of adaptive algorithms based on nonlinear functions as a criterion to be applied upon the error, that we want to minimize. Such a development is based upon the use of high order statistics to obtain additional information of the signals involved in the process, intending to enhance the adaptive filtering performance. We derive equations based upon the Taylor s series expansion of the nonlinear functions in order to obtain criterions that guarantee convergence. We also make a study about the covariance of the weight vector on steady state and determine equations that measure the time constant of the adaptive process. We present the sigmoidal algorithm that uses the function Ln(cosh ") as criterion. Simulations of this algorithm are performed to validate the theory and it is also applied to obtain the deterministic components of real impedance cardiographic signals. / Neste trabalho é desenvolvida uma famılia de algoritmos adaptativos baseados em funções não lineares como critério a ser aplicado sobre o erro, o qual deseja-se minimizar. Tal desenvolvimento baseia-se na utilização de estatısticas de alta ordem para a obtenção de mais informações sobre os sinais envolvidos no processo, com o objetivo de melhorar a performance de um filtro adaptativo. Derivamos equações, baseadas na expansão em séries de Taylor das funções não lineares, para a obtenção de critérios que garantam a convergência. Também fazemos um estudo da covariância do vetor peso em regime estacionário e determinamos equações que mensurem a constante de tempo do processo adaptativo. Apresentamos o algoritmo sigmoidal, que utiliza como critério a função Ln(cosh "). Foram feitas simulações com este algoritmo para validar a teoria apresentada, e também o aplicamos para a obtenção das componentes determinısticas de sinais reais de impedância cardiográfica.

algoritmos adaptativos

filtragem adaptativa

impedância cardiográfica

adaptive algorithms

adaptive filtering

cardiographic impedance

Estudo e avaliação de técnicas de processamento do sinal mioelétrico para o controle de sistemas de reabilitação. / Study and evaluation of techniques for myoelectric signal processing to control rehabilitation systems.

Rodrigo Lício Ortolan

05 April 2002

Este trabalho tem a finalidade de analisar algumas técnicas de processamento do sinal mioelétrico, de forma a possibilitar uma posterior implementação de um circuito, que reconheça este sinal e apresente como saída um sinal de controle a ser utilizado em sistemas de reabilitação. Foram simuladas e avaliadas três técnicas de filtragem para o sinal mioelétrico, a fim de atenuar a interferência dos principais ruídos que corrompem este sinal. As técnicas avaliadas foram: filtragem digital clássica; cancelamento de ruído adaptativo e reconstrução do sinal por meio das componentes obtidas pela transformada wavelet. Também foi implementado e analisado um sistema simplificado de reconhecimento dos padrões para este sinal, realizado por meio de uma rede neural artificial, em que foi aplicado em sua entrada o próprio sinal mioelétrico e não suas características obtidas por processamentos matemáticos. Diante dos resultados obtidos os canceladores de ruído adaptativos apresentaram melhores resultados com relação às outras técnicas de filtragem. Apesar de não ter sido adequada para a filtragem, a transformada wavelet mostrou-se uma poderosa ferramenta de análise de sinais, em virtude da sua característica multiresolução. A técnica utilizada para reconhecer os padrões do sinal mostrou bons resultados com os sinais analisados. / This work has the purpose to analyze some techniques for myoelectric signal processing, towards a subsequent implementation of a circuit which can recognize this signal and present as output a control signal to be used in rehabilitation systems. Simulation and evaluation of three filtering techniques for the myoelectric signal were done in order to attenuate the main interferences of noises which corrupt this signal. The evaluated techniques were: classic digital filtering; adaptive noise cancelling and the signal reconstruction through the obtained components by the wavelet transform. A simplified system of pattern recognition for this signal also was implemented and analyzed, accomplished through an artificial neural network. The myoelectric signal itself was applied to the input instead of its characteristics obtained by mathematical processing. According to the results obtained the adaptive noise cancelling presented better results in comparison to the other filtering techniques. Despite not being adequate for filtering, the wavelet transform proved to be a powerful tool for signal analysis, by virtue of its multiresolution characteristics. The technique used to recognize the signal patterns has shown good results with the analyzed signals.

engenharia de reabilitação

filtragem adaptativa

processamento digital de sinais

reconhecimento de padrões

sinais mioelétricos

transformada wavelet

adaptive filtering

digital signal processing

myoelectric signals

pattern recognition

rehabilitation engineering

wavelet transform

Système d'annulation d'écho pour répéteur iso-fréquence : contribution à l'élaboration d'un répéteur numérique de nouvelle génération / Echo cancellation system for iso-frequency repeaters : contribution to the development of a new generation digital repeater

Zeher, Amar

17 November 2014

Le déploiement des répéteurs iso-fréquence est une solution économique pour étendre la couverture d’un émetteur principal aux zones d’ombre. Cependant, ce mode de déploiement fait apparaître le phénomène des échos radio-fréquence entre antennes d’émission et de réception du répéteur. Selon les standards, un écho aussi faible soit-il réduit le débit de la liaison radio, tandis qu’un écho fort fait courir au répéteur le risque d’endommager ses circuits électroniques, ces risques sont dûs aux ondulations de puissance créées par les échos. L’objectif de cette thèse à caractère industriel est d’étudier ce phénomène naturel en considérant des signaux provenant de différents standards des télécommunications. Cette étude permet une caractérisation des échos radio-fréquence pour mieux s’orienter vers une solution optimisée et industriellement réalisable.Nous nous sommes orientés vers la solution du traitement du signal avancé en favorisant le filtrage adaptatif pour sa rapidité de convergence et sa simplicité relative d’implantation matérielle. Les circuits reconfigurables sont retenus pour leur prix et leur souplesse. L’implantation des solutions est effectuée en virgule fixe afin de satisfaire les exigences de réactivité. Durant la mise en oeuvre de la solution anti-écho, nous avons proposé une multitude de solutions numériques souples et fiables. À partir de ce constat, notre partenaire industriel a décidé de généraliser ce mode de traitement par le développement, la fabrication et la commercialisation de répéteurs de nouvelle génération entièrement numériques. / On-frequency repeaters are a cost-effective solution to extend coverage and enhance wireless communications, especially in shadow areas. However, coupling between the receiving antenna and the transmitting antenna, called radio frequency echo, increases modulation errors and creates oscillations in the system when the echo power is high. According to the communication standards, extremely weak echoes decrease the transmission rate, while strong echoes damage electroni ccircuits because of power peaks. This thesis aims at characterizing the echo phenomenon under different modulations, and proposing an optimized solution directly integrated to industry. We have turned to digital solutions especially the adaptive because of their high convergence rate and their simplicity to be implemented. The programmable circuits are chosen for their attractive price and their flexibility. When implementing echo cancellation solution, we proposed several reliable solutions, showing that digital processing is much more beneficial. For this reason, digital solutions are generalized, and the new generation of repeaters is fully digital.

Répéteur

Couverture

Iso-fréquence

Annulation d’écho

Filtre adaptatif

Détection

Prédistorsion

FPGA

Microprocesseur

Repeater

Coverage

On-frequency

Echo cancellation

Adaptive filtering

Detection

Predistortion

FPGA

Microprocessor

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