Global ETD Search

281	Développement d'un capteur de déformation MEMS sans fil Merdassi, Adel January 2011 (has links) Il y a un besoin de mesures de vibration, tel que dans l'automobile pour le contrôle actif du bruit acoustique. Les microsystèmes électromécaniques (MEMS) et les technologies sans fils sont des technologies de plus en plus répandues pour l'implémentation de capteurs. Ce projet vise donc le développement de capteurs de déformation en utilisant une solution sans fil pour l'acquisition des mesures de la vibration, avec les technologies MEMS. Ce projet de recherche utilise la technologie des systèmes RFID passifs pour la communication, intégrée avec un transducteur de déformation MEMS pour la mesure. Le capteur consiste en une antenne reliée à un transducteur MEMS capacitif par l'entremise d'une ligne de transmission avec des discontinuités. Les déformations de la structure sur laquelle le capteur est fixé sont traduites en changement de capacité du transducteur, ce qui engendre un retard dans le signal réfléchi par l'antenne. Une étude de l'état de l'art des principes de communication et de transduction a permis de comparer les avantages et inconvénients des approches. Une modélisation analytique faite sur différents types de transduction a conduit à une combinaison optimale faisant intervenir un transducteur type capacitif. Pour atteindre une taille du capteur de l'ordre du centimètre, le système travaille à une fréquence micro-onde fixée à 24,125 GHz. Un dispositif fût alors conçu, incluant la ligne de transmission avec des discontinuités pour l'identification du capteur ainsi que le transducteur capacitif avec peignes interdigités et ressorts en silicium. La conception d'un tel capteur permet d'aboutir à une sensibilité de 11ps/[epsilon] avec une bonne linéarité sur une plage de mesure [0..2500[micro][epsilon]]. Un procédé de microfabrication du transducteur MEMS est aussi proposé, ainsi qu'une approche pour la fabrication pour les éléments RF sur un substrat d'alumine et leur intégration. Transmission sans fil Microfabrication RFID MEMS Vibration Déformation Capteur
282	Advanced interface systems for readout, control, and self-calibration of MEMS resonant gyroscopes Norouz Pour Shirazi, Arashk 27 May 2016 (has links) MEMS gyroscopes have become an essential component in consumer, industrial and automotive applications, owing to their small form factor and low production cost. However, their poor stability, also known as drift, has hindered their penetration into high-end tactical and navigation applications, where highly stable bias and scale factor are required over long period of time to avoid significant positioning error. Improving the long-term stability of MEMS gyroscopes has created new challenges in both the physical sensor design and fabrication, as well as the system architecture used for interfacing with the physical sensor. The objective of this research is to develop interface circuits and systems for in-situ control and self-calibration of MEMS resonators and resonant gyroscopes to enhance the stability of bias and scale factor without the need for any mechanical rotary stage, or expensive bulky lab characterization equipment. The self-calibration techniques developed in this work provide 1-2 orders of magnitude improvement in the drift of bias and scale factor of a resonant gyroscope over temperature and time. Electrical self-calibration Inertial sensors Interface circuits MEMS gyroscopes
283	Eye Movement Event Detection for Wearable Eye Trackers Hossain, Akdas, Miléus, Emma January 2016 (has links) Eye tracking research is a growing area and the fields as where eye trackingcould be used in research are large. To understand the eye tracking data dif-ferent filters are used to classify the measured eye movements. To get accu-rate classification this thesis has investigated the possibility to measure bothhead movements and eye movements in order to improve the estimated gazepoint.The thesis investigates the difference in using head movement compensationwith a velocity based filter, I-VT filter, to using the same filter without headmovement compensation. Further on different velocity thresholds are testedto find where the performance of the filter is the best. The study is made with amobile eye tracker, where this problem exist since you have no absolute frameof reference as opposed to when using remote eye trackers. The head move-ment compensation shows promising results with higher precision overall. Mobile Eye Tracking I-VT Filter MEMS Gyroscope
284	Electrodeposition and characterisation of thin films for the fabrication of microinductors Murray, Jeremy January 2014 (has links) Stress in electrochemically deposited (ECD) magnetic films is an important parameter that can have a critical effect on the performance of MEMS devices such as microinductors. This is especially the case when thick layers of materials are required and where it is important to monitor and hence control stress to prevent cracking and delamination. The reliability of devices, therefore, deeply depends on process parameters and conditions used in depositing these materials on silicon wafers. A MEMS technique for measuring stress spatially around such a wafer has been developed and used to characterise the materials involved in the fabrication of a microinductor. This thesis discusses the design and fabrication of test structures, along with a custom built automatic measurement technique to wafer map the spatial variation of strain, on any sized wafers. The effect of agitation on the grain structure of NiFe has been observed to affect strain which were spatially mapped and correlated with the film composition and thickness. Film uniformity were also shown to improve in the absence of agitation in the bath. To further understand the fundamentals of ECD small scale beaker level galvano-static experiments have been employed to use the same test structures fabricated on small Si chips. The effects of hydrogen evolution on film stress and efficiency with the inclusion of boric acid and saccharin, have been discussed. It was concluded that the tensile stress developed in Ni and NiFe films have an inversely proportional relationship with the plating efficiency. The characterisation of electrodeposited copper films is also of importance as copper films are integrated with magnetic materials in the form of windings for microinductors. The variations in recrystallization and evolution of grains of ECD copper, is for the first time demonstrated spatially using the test structures. The effect of additives in bath on film uniformity was investigated and it was observed that with carrier and additive together the three phases of self annealing were more pronounced. Finally the use of these strain test structures have been demonstrated on thick polymer SU-8 films, which is employed as a structural material in microinductors. The effect of UV exposure dose on the cross linking properties of SU-8 has also been studied. It was observed that non-uniformity in the coated film thickness over the wafer can cause variations in the UV exposure during photolithography that effects the cross linking of the polymer hence, inducing different levels of tensile stress in the material. This unique methodology has therefore opened up many possibilities and can be used for characterising newer materials employed in MEMS, fine-tuning the manufacturing processes to achieve set goals in terms of material properties as well as uniformity and gaining a better understanding of the influence of processing conditions on the produced films. 621.381
285	SUBMINIATURE GPS INERTIAL TIME SPACE POSITION INFORMATION Khosrowabadi, Allen, Gurr, Richard, Fleishans, Amy 10 1900 (has links) International Telemetering Conference Proceedings / October 23-26, 2000 / Town & Country Hotel and Conference Center, San Diego, California / In the past few years, GPS has proven itself as an effective source of time space position information (TSPI) data for air vehicles. Currently, GPS truth systems are used to track aircraft ranging from low dynamic vehicles to high dynamic fighters. However, low-cost GPS TSPI instrumentation is not currently available for stores and weapons delivered by air vehicles. To date, data is collected by tracking dropped items using radar or optical means. This process is costly and time consuming. The purpose of this project is to leverage the recent advances in micro-electromechanical systems (MEMS) technology to develop a subminiature, inexpensive, low power, disposable telemetrytransmitting package. The purpose of this transmitting package is to up-link the GPS positional data from the weapon or store to the host aircraft. This data is then retransmitted by the host aircraft to a ground station and/or recorded on board for post processing. The transmission of the data to the host aircraft can provide near real- time position data for the released object. The transmitting package must have a unique identification method for application in tracking multiple objects. Since most of the systems used in weapons testing will be destroyed, it is extremely important to keep the development and maintenance cost low. In addition, the package must be non-intrusive to avoid any significant modification to the weapon and to facilitate quick instrumentation of the weapon for test and evaluation. Micro-electromechanical systems Smart GPS antenna MEMS micro-machine
286	Silicon-embedded magnetic components for on-chip integrated power applications Yu, Xuehong 07 January 2016 (has links) The objective of the proposed research is to design, fabricate, characterize and test silicon-embedded magnetic components for on-chip integrated power applications. Driven by the trend towards continued system multi-functionality and miniaturization, MEMS technology can be used to enable fabrication of three-dimensional (3-D) functional devices into the silicon bulk, taking advantage of the 'dead volume' in the substrate and achieving a greater level of miniaturization and integration. As an example, one of the challenges in realizing ultra-compact high-frequency power converters lies in the integration of magnetic components due to their relatively large volume. Embedding 3-D magnetic components within the wafer volume and implementing high-power, through-wafer interconnect for connection to circuitry on the wafer surface is a promising solution for achieving ultra-compact power converters, in which digital control circuitry and power switches are located on the wafer surface, and suitable magnetic components are embedded within the silicon substrate. In order to do this, key tasks in the following areas have been accomplished: development of new fabrication technologies for silicon embedding and 3-D structure realization; creation of high-current, through-wafer interconnects for connection of the device to circuitry; ability to incorporate a variety of magnetic materials when performance enhancement of the device is needed; exploration of a new design space for the devices due to ultra-compactness and silicon interaction; understanding of the complicated loss mechanisms in the embedded devices; and demonstration of device performance and in-circuit operation. Silicon embedding Toroidal inductors Power supply on chip MEMS
287	RECONFIGURABLE PATCH ANTENNA FOR FREQUENCY DIVERSITY WITH HIGH FREQUENCY RATIO (1.6:1) Jung, Chang won, Lee, Ming-jer, Liu, Sunan, Li, G. P., De Flaviis, Franco 10 1900 (has links) ITC/USA 2005 Conference Proceedings / The Forty-First Annual International Telemetering Conference and Technical Exhibition / October 24-27, 2005 / Riviera Hotel & Convention Center, Las Vegas, Nevada / Reconfigurable patch antenna integrated with RF mircoelectromechanical system (MEMS) switches is presented in this paper. The proposed antenna radiates circularly polarized wave at selectable dual frequencies (4.7 GHz and 7.5GHz) of high frequency ratio (1.6:1). The switches are incorporated into the diagonally-fed square patch for controlling the operation frequency, and a rectangular stub attached to the edge of the patch acts as the perturbation to produce the circular polarization. Gain of proposed antenna is 5 - 6dBi, and axial ratio satisfies 3dB criterion at both operating frequencies. The switches are monolithically integrated on quartz substrate. The antenna can be used in applications requiring frequency diversity of remarkable high frequency ratio. Reconfigurable antenna RF-MEMS switch High-frequency ratio
288	Active learning module assessment and the development and testing of a new prototyping planning tool Dunlap, Brock Usher 07 October 2014 (has links) This thesis contains the research findings from my participation in two research projects. The first is the development and assessment of Active Learning Modules (ALMs) for engineering students. The ALMs assist students in learning complex Finite Element Analysis (FEA) principles. We measure the effectiveness of the modules by issuing pre- and post-module quizzes and analyze the differences of the quiz scores. Active learning modules are used to meet the needs of all students’ learning styles. Each student who uses an ALM takes a series of learning style assessment quizzes (MBTI, LIS …). We statistically compare the learning styles and quiz scores to ensure all learning styles are improving equally well. In cases where they are not, we created a tool to make suggestions to the ALM developer on how to adjust the ALM to meet the needs of the outlying learning style group(s). Following modification, the implementation and evaluation process of the ALM is repeated. My second area of research focused on the development of a concise prototype strategy development tool. This tool guides engineering product development teams through six critical prototype strategy choices: (1) How many concepts should be prototyped? (2) How many iterations of a concept should be built? (3) Should the prototype be virtual or physical? (4) Should subsystems be isolated? (5) Should the prototype be scaled? (6) Should the design requirements be temporarily relaxed? This list of choices is not comprehensive but served as a starting point for this groundbreaking research. The tool was tested at The University of Texas at Austin and the United States Air Force Academy. Results indicate the method did improve students’ performance across a number of assessment metrics. / text Prototyping Active learning Prototype strategy Learning modules MEMS Prototyping
289	Force Interaction and Sensing in Bio-micromanipulation Ghanbari, Ali January 2012 (has links) Micromanipulation is considered a challenging task which requires high precision motion and measurement at the micro scale. When micromanipulation is concerned with living organisms important considerations need to be addressed. These include the physical or chemical properties of micro-organisms, living conditions, responses to the environment and achieving suitably delicate manipulation. Bio-micromanipulation can include micro surgery or cell injection operations, or to determine interaction forces as the basis to investigate behavior and properties of living micro-organisms. In order to achieve suitable bio-micromanipulation appropriate processes and/or sensory systems need to be investigated. This thesis aims to look into the force interaction and sensing addressing two distinctive challenges in the field of bio-micromanipulation. To this end, this thesis presents two major contributions to advancing bio-micromanipulation. Firstly, a novel Haptic Microrobotic Cell Injection System is introduced which is able to assist a bio-operator through haptic interaction. The system introduces a mapping framework which provides an intuitive method for the bio-operator to maneuver the micropipette in a manner similar to handheld needle insertion. To accurately control the microrobot, a neuro-fuzzy modeling and control scheme has been developed. Volumetric, axial and planar haptic virtual fixtures are introduced to guide the bio-operator during cell injection. Aside from improving real-time operator performance using the physical system, the system is novel in facilitating virtual offline operator training. Secondly, a first-of-its-kind micro-pillar based on-chip system for dynamic force measurement of C. elegans motion is introduced. The system comprises a microfabricated PDMS device to direct C. elegans into a matrix of micropillars within a channel mimicking its dwelling environment. An image processing algorithm is able to track the interaction of the C. elegans with the pillars and estimate contact forces based on micropillar deflections. The developed micropillar system is capable of measuring the force with sub-micron resolution while providing a continuous force output spectrum. bio-micromanipulation haptic microrobotic cell injection bio-MEMS C. elegans
290	Real-time Cycle-slip Detection and Correction for Land Vehicle Navigation using Inertial Aiding Karaim, MALEK 07 May 2013 (has links) Processing GPS carrier-phase measurements can provide high positioning accuracy for several navigation applications. However, if not detected, cycle slips in the measured phase can strongly deteriorate the positioning accuracy. Cycle slips frequently occur in areas surrounded by trees, buildings, and other obstacles. The dynamics experienced by the GPS receiver in kinematic mode of navigation also increases the possibility of cycle slips. Detection and correction of these cycle-slips is essential for reliable navigation. One way of detecting and correcting for cycle slips is to use another system to be integrated with GPS. Inertial Navigation Systems (INS), using three-axis accelerometers and three-axis gyroscopes, is integrated with GPS to provide more reliable navigation solution. Moreover, INS was utilized in the past for GPS cycle slip detection and correction. For low cost applications, Micro-Electro-Mechanical-Systems (MEMS) accelerometers and gyroscopes are used inside INS. For land navigation, reduced inertial sensor system (RISS) utilizing two accelerometers, one gyroscope, and the vehicle odometer was suggested. MEMS-based RISS has the advantage of using less number of MEMS-based gyroscopes and accelerometers thus reducing the overall cost and avoiding the complex error characteristics associated with MEMS sensors. In this thesis, we investigate the use of MEMS – based RISS to aid GPS and detect and correct for cycle slips. The Kalman filter was employed in centralized fashion to integrate the measurements from both GPS and RISS. This thesis research also offers a new threshold selection criterion resulting in a more robust cycle slip detection and correction. The proposed method was tested in different scenarios of road tests in land vehicle. Results show accuracy iii improvement over the conventional double differenced pseudoranges-based integrated system. Moreover, the adaptive selection criterion of the detection threshold proposed in this thesis improves the detection rate, especially in the case of small-sized cycle slips. / Thesis (Master, Electrical & Computer Engineering) -- Queen's University, 2013-05-06 18:11:57.076 GPS/INS Integration RISS MEMS Cycle-slip Detection and Correction

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