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1	Stability Analysis of a MEMS Acceleration Sensor Wolfram, Heiko, Dötzel, Wolfram 05 February 2007 (has links) (PDF) The electrostatic actuation with its several advantages is the main principle for micro-electro-mechanical systems (MEMS). One major drawback is the nonlinear behavior, which results into instability, known as the electrostatic pull-in effect. This effect might also push a closed-loop configuration into instability and thus makes a linear time-invariant control inapplicable to the system. The paper investigates the stability of an acceleration sensor in closed-loop operation with this setting. A simplified controller adjustment gives a first insight into this topic. Practical implementations saturate on the quantizer's full-scale value, which is also considered in the stability analysis. Numerical phase-plane analysis verifies the stability and shows further surprising results. Acceleration Sensor Capacitive Sensor Electrostatic Pull-in Unstable Pole ddc:620 Beschleunigungssensor Elektrostatik Ljapunov-Methode Regelung Stabilität
2	Tillståndskontroll av spårväxlar med mätutrustning monterad på tåg i reguljärtrafik Rengmyr, Simon January 2017 (has links) From 2000 to 2015, the cost of operation and maintenance (including reinvestment) and traffic control has increased from approximately three billion to over nine billion Swedish kronor annually. By making more frequent measurements of track irregularities and identifying trends earlier, accurate and effective maintenance can be performed. Therefore, in the industry and academy, different measurement solutions are tested to measure the state of railroad tracks in a simple and more frequent manner. One of the solutions is to use measuring systems mounted on trains in regular traffic. By using regular scheduled services, a higher cost effectiveness regarding inspection frequency can be achieved. When the measuring equipment is mounted on freight trains, a measurement with considerably higher axle load can also be performed. In the course of this work, a literature study have been conducted and a number of scientific articles and reports have been studied at depth. There is a number of different systems that have been manufactured to be mounted on rolling stock in regular service. Different solutions are applied to perform the measurements. Acceleration sensors are robust and reliable, which is necessary because they will be mounted in an exposed environment. A difference that has been identified is the installation of accelerometer sensors that are either mounted before or after the primary suspension. Before suspension the sensors are mounted on the axle box and, after suspension the sensors are mounted on the train bogie. The engineering company Damill is working within monitoring solutions and has developed equipment for mounting on trains in regular traffic called Tracklogger. Earlier evaluations of the equipment have been made with focus on comparison with machine inspections. There is a difference between the technology used in track recording vehicles and the technology that Tracklogger uses, such comparison is not entirely appropriate. In discussion with Damill the focus of this work has been to see if recordings of switches can be linked to maintenance actions. Since the equipment is in the development stage it is important that the measurement data collected is critically reviewed with regard to what information it delivers. The measurements have been carried out on switches in the main train track on track number 119 between Luleå and Boden and the mining company LKAB's ore wagon has been a tool carrier. Five out of eight cases, a maintenance action can be linked to reduced measured values of switches with fixed crossing points. In one case, maintenance action has increased the measured value. In two cases, there is no signifcant difference in the measured value associated with maintenance actions. In previous evaluation, it was determined that it is good repeatability in the measured position, but not as high repeatability in the measured size. A number of switches have been studied to check the repeatability of the measurement. As the train runs in acircle run in Luleå harbor, there will be a limited number of occasions the equipment is running in the same direction in combination with the sensors on the same axle in the bogie, which may effect the measurement results. When analyzing the repeatability of five passages where the direction of travel is not taken into account, it is determined that three out of five passages show a good repeatability. The repeatability of the measurement is suspected of being related to the condition, as significantly greater differences in the measured signal are obtained just before a maintenance action has been taken. switches crossings onboard system crossingpoint acceleration sensor accelerometer vibration measurement spårväxlar spårväxel ombordsystem korsningsspets accelerationsgivare accelerometer vibrationsmätning Infrastructure Engineering Infrastrukturteknik
3	Model Building, Control Design and Practical Implementation of a High Precision, High Dynamical MEMS Acceleration Sensor Wolfram, Heiko 22 December 2005 (has links) (PDF) This paper presents the whole process of building up a high precision, high dynamical MEMS acceleration sensor. The first samples have achieved a resolution of better than 500 micro g and a bandwidth of more than 200 Hz. The sensor fabrication technology is shortly covered in the paper. A theoretical model is built from the physical principles of the complete sensor system, consisting of the MEMS sensor, the charge amplifier and the PWM driver for the sensor element. The mathematical modeling also covers problems during startup. A reduced order model of the entire system is used to design a robust control with the Mixed-Sensitivity H-infinity Approach. Since the system has an unstable pole, imposed by the electrostatic field and time delay, caused by A/D-D/A conversation delay and DSP computing time, limitations for the control design are given. The theoretical model might be inaccurate or lacks of completeness, because the parameters for the theoretical model building vary from sample to sample or might be not known. A new identification scheme for open or closed-loop operation is deployed to obtain directly from the samples the parameters of the mechanical system and the voltage dependent gains. The focus of this paper is the complete system development and identification process including practical tests in a DSP TI-TMS320C3000 environment. Acceleration Sensor H-infinity Control Identification Mixed-Sensitivity Approach Model Building ddc:620 Kapazitiver Sensor Mathematisches Modell Regelungstechnik
4	Model Building, Control Design and Practical Implementation of a High Precision, High Dynamical MEMS Acceleration Sensor Wolfram, Heiko 22 December 2005 (has links) This paper presents the whole process of building up a high precision, high dynamical MEMS acceleration sensor. The first samples have achieved a resolution of better than 500 micro g and a bandwidth of more than 200 Hz. The sensor fabrication technology is shortly covered in the paper. A theoretical model is built from the physical principles of the complete sensor system, consisting of the MEMS sensor, the charge amplifier and the PWM driver for the sensor element. The mathematical modeling also covers problems during startup. A reduced order model of the entire system is used to design a robust control with the Mixed-Sensitivity H-infinity Approach. Since the system has an unstable pole, imposed by the electrostatic field and time delay, caused by A/D-D/A conversation delay and DSP computing time, limitations for the control design are given. The theoretical model might be inaccurate or lacks of completeness, because the parameters for the theoretical model building vary from sample to sample or might be not known. A new identification scheme for open or closed-loop operation is deployed to obtain directly from the samples the parameters of the mechanical system and the voltage dependent gains. The focus of this paper is the complete system development and identification process including practical tests in a DSP TI-TMS320C3000 environment. info:eu-repo/classification/ddc/620 ddc:620 Kapazitiver Sensor Mathematisches Modell Regelungstechnik Acceleration Sensor H-infinity Control Identification Mixed-Sensitivity Approach Model Building
5	Stability Analysis of a MEMS Acceleration Sensor Wolfram, Heiko, Dötzel, Wolfram 05 February 2007 (has links) The electrostatic actuation with its several advantages is the main principle for micro-electro-mechanical systems (MEMS). One major drawback is the nonlinear behavior, which results into instability, known as the electrostatic pull-in effect. This effect might also push a closed-loop configuration into instability and thus makes a linear time-invariant control inapplicable to the system. The paper investigates the stability of an acceleration sensor in closed-loop operation with this setting. A simplified controller adjustment gives a first insight into this topic. Practical implementations saturate on the quantizer's full-scale value, which is also considered in the stability analysis. Numerical phase-plane analysis verifies the stability and shows further surprising results. info:eu-repo/classification/ddc/620 ddc:620 Beschleunigungssensor Elektrostatik Ljapunov-Methode Regelung Stabilität Acceleration Sensor Capacitive Sensor Electrostatic Pull-in Unstable Pole
6	Entwicklungen und Untersuchungen zur Objektivierung von Gangbildveränderungen unter Laufband- und Terrainverhältnissen / Developments and investigations of the objectification of Gait changes in treadmill and terrain conditions Staab, Wieland 31 January 2012 (has links) No description available. 610 Medizin, Gesundheit Medicine EFL(FCE)-Verfahren degenerative Skeletterkrankungen EFL (FCE) method degenerative skeletal disorders 44.00 MED 490: Orthopädie
7	Sensordatenfusion zur robusten Bewegungsschätzung eines autonomen Flugroboters Wunschel, Daniel 15 March 2012 (has links) (PDF) Eine Voraussetzung um einen Flugregler für Flugroboter zu realisieren, ist die Wahrnehmung der Bewegungen dieses Roboters. Diese Arbeit beschreibt einen Ansatz zur Schätzung der Bewegung eines autonomen Flugroboters unter Verwendung relativ einfacher, leichter und kostengünstiger Sensoren. Mittels eines Erweiterten Kalman Filters werden Beschleunigungssensoren, Gyroskope, ein Ultraschallsensor, sowie ein Sensor zu Messung des optischen Flusses zu einer robusten Bewegungsschätzung kombiniert. Dabei wurden die einzelnen Sensoren hinsichtlich der Eigenschaften experimentell untersucht, welche für die anschließende Erstellung des Filters relevant sind. Am Ende werden die Resultate des Filters mit den Ergebnissen einer Simulation und eines externen Tracking-Systems verglichen. Ultraschallsensor EKF Kalman Filter Extended Kalman Filter Optischer Fluss Ultraschallsensor IMU Bewegungsschätzung EKF Extended Kalman Filter inertial measurement unit IMU optical flow motion estimation ultrasonic range finder sensor fusion acceleration sensor gyroscope ddc:620 Ultraschallsensor Datenfusion Gyroskop Beschleunigungssensor Zustandsschätzung Optischer Sensor Kalman-Filter
8	Sensordatenfusion zur robusten Bewegungsschätzung eines autonomen Flugroboters Wunschel, Daniel 24 October 2011 (has links) Eine Voraussetzung um einen Flugregler für Flugroboter zu realisieren, ist die Wahrnehmung der Bewegungen dieses Roboters. Diese Arbeit beschreibt einen Ansatz zur Schätzung der Bewegung eines autonomen Flugroboters unter Verwendung relativ einfacher, leichter und kostengünstiger Sensoren. Mittels eines Erweiterten Kalman Filters werden Beschleunigungssensoren, Gyroskope, ein Ultraschallsensor, sowie ein Sensor zu Messung des optischen Flusses zu einer robusten Bewegungsschätzung kombiniert. Dabei wurden die einzelnen Sensoren hinsichtlich der Eigenschaften experimentell untersucht, welche für die anschließende Erstellung des Filters relevant sind. Am Ende werden die Resultate des Filters mit den Ergebnissen einer Simulation und eines externen Tracking-Systems verglichen. info:eu-repo/classification/ddc/620 ddc:620

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