Global ETD Search

61	A wide dynamic range high-q high-frequency bandpass filter with an automatic quality factor tuning scheme Kumar, Ajay 09 January 2009 (has links) An 80 MHz bandpass filter with a tunable quality factor of 16∼44 using an improved transconductor circuit is presented. A noise optimized biquad structure for high-Q, high- frequency bandpass filter is proposed. The quality factor of the filter is tuned using a new quality factor locked loop algorithm. It was shown that a second-order quality factor locked loop is necessary and sufficient to tune the quality factor of a bandpass filter with zero steady state error. The accuracy, mismatch, and sensitivty analysis of the new tuning scheme was performed and analyzed. Based on the proposed noise optimized filter structure and new quality factor tuning scheme, a biquad filter was designed and fabricated in 0.25 μm BiCMOS process. The measured results show that the biquad filter achieves a SNR of 45 dB at IMD of 40 dB. The P-1dB compression point and IIP3 of the filter are -10 dBm and -2.68 dBm, respectively. The proposed biquad filter and quality factor tuning scheme consumes 58mW and 13 mW of power at 3.3 V supply. Tuning GM-C Filter Analog filter Continuous time MLL QLL Quality factor Electric filters, Bandpass Radio Transmitter-receivers Wireless communication systems
62	Optimization of piezoresistive cantilevers for static and dynamic sensing applications Naeli, Kianoush 03 April 2009 (has links) The presented work aims to optimize the performance of piezoresistive cantilevers in cases where the output signal originates either from a static deflection of the cantilever or from the dynamic (resonance) characteristic of the beam. Based on a new stress concentration technique, which utilizes silicon beams and wires embedded in the cantilever, the force sensitivity of the cantilever is increased up to 8 fold with only about a 15% decrease in the cantilever stiffness. Moreover, the developed stress-concentrating cantilevers show almost the same resonance characteristic as conventional cantilevers. The focus of the second part of the present work is to provide guidelines for designing rectangular silicon cantilever beams to achieve maximum quality factors for the fundamental and higher flexural resonance at atmospheric pressure. The applied methodology is based on experimental data acquisition of resonance characteristics of silicon cantilevers, combined with modification of analytical damping models to match the measurement data. To this end, rectangular silicon cantilever beams with thicknesses of 5, 7, 8, 11 and 17 um and lengths and widths ranging from 70 to 1050 um and 80 to 230 um, respectively, have been fabricated and tested. To better describe the experimental data, modified models for air damping have been developed. Moreover, to better understand the damping mechanisms in a resonant cantilever system, analytical models have been developed to describe the cantilever effective mass in any flexural resonance mode. To be able to extract reliable Q-factor data for low signal-to-noise ratios, a new iterative curve fitting technique is developed and implemented. To address the challenge of frequency drift in (mass-sensitive) resonant sensors, and especially cantilever-based devices, the last part of the research deals with a novel compensation technique to cancel the unwanted environmental effects (e.g., temperature and humidity). This technique is based on exploring the resonance frequency difference of two flexural modes. Experimental data show improvements in temperature and humidity coefficients of frequency from -19.5 to 0.2 ppm/˚C and from 0.7 to -0.03 ppm/%RH, respectively. The last part of the work also aims on techniques to enhance or suppress the flexural vibration amplitude in desired overtones. Quality factor Resonator Cantilever MEMS Air damping Flexural mode Stress Concentration Temperature compensation Mass sensor Piezoresistance Strain gauge Detectors Piezoelectric transducers
63	A novel induction heating system using multilevel neutral point clamped inverter Al Shammeri, Bashar Mohammed Flayyih January 2017 (has links) This thesis investigates a novel DC/AC resonant inverter of Induction Heating (IH) system presenting a Multilevel Neutral Point Clamped (MNPCI) topology, as a new part of power supply design. The main function of the prototype is to provide a maximum and steady state power transfer from converter to the resonant load tank, by achieving zero current switching (ZCS) with selecting the best design of load tank topology, and utilizing the advantage aspects of both the Voltage Fed Inverter (VFI) and Current Fed Inverter (CFI) kinds, therefore it can considered as a hybrid-inverter (HVCFI) category . The new design benefits from series resonant inverter design through using two bulk voltage source capacitors to feed a constant voltage delivery to the MNPCI inverter with half the DC rail voltage to decrease the switching losses and mitigate the over voltage surge occurred in inverter switches during operation which may cause damage when dealing with high power systems. Besides, the design profits from the resonant load topology of parallel resonant inverter, through using the LLC resonant load tank. The design gives the advantage of having an output current gain value of about Quality Factor (Q) times the inverter current and absorbs the parasitic components. On the contrary, decreasing inverter current means decreasing the switching frequency and thus, decreasing the switching losses of the system. This aspect increases the output power, which increases the heating efficiency. In order for the proposed system to be more reliable and matches the characteristics of IH process , the prototype is modelled with a variable LLC topology instead of fixed load parameters with achieving soft switching mode of ZCS and zero voltage switching (ZVS) at all load conditions and a tiny phase shift angle between output current and voltage, which might be neglected. To achieve the goal of reducing harmonic distortion, a new harmonic control modulation is introduced, by controlling the ON switching time to obtain minimum Total Harmonic Distortion (THD) content accompanied with optimum power for heating energy. 621.402
64	Lignes de propagation intégrées à fort facteur de qualité en technologie CMOS. Application à la synthèse de circuits passifs millimétriques / High quality factor integrated transmission lines in CMOS technology - Application to millimetre passive circuits Franc, Anne-Laure 06 July 2011 (has links) L’objectif de ces travaux est le développement en technologie intégrée standard d’une topologiede ligne de propagation optimisée en termes de pertes, d’encombrement et de facteur de qualitéaux fréquences millimétriques. Cette topologie nommée S-CPW (Shielded CoPlanarWaveguide) utilise le phénomène d’ondes lentes afin de miniaturiser longitudinalement la ligned’un facteur compris entre 1,3 et 3,2 par rapport à des topologies classiques. Disposantégalement de faibles pertes, les lignes développées présentent un facteur de qualité élevé parfoissupérieur à 40, à 60 GHz. A partir de l’étude du champ électromagnétique dans la structure, unmodèle électrique a été développé. C’est le premier modèle dans la littérature prenant en compteles pertes dans ce type de guide d’onde. Plusieurs dispositifs passifs intégrés réalisés avec deslignes S-CPW dans différentes technologies CMOS ont été caractérisés jusqu’à 110GHz. Lacompacité et les faibles pertes d’insertion obtenues pour la mesure de filtres à stubs et dediviseurs de puissance permettent de réussir l’intégration de circuits passifs compacts entechnologie microélectronique CMOS standard aux fréquences millimétriques. / This work focuses on high-performance S-CPW (Shielded CoPlanar Waveguide) transmissionlines in classical CMOS integrated technologies for the millimeter-wave frequency band.Thanks to an important slow-wave phenomenon, the physical length of S-CPW decreases by afactor from 1.3 to 3.2 compared with classical transmission lines. Presenting also lowattenuation loss, the developed transmission lines show very high quality factor (higher than 40at 60 GHz). The precise study of the electromagnetism field leads to an electrical model forS-CPWs. This is the first model that takes the losses in this topology into account. Then, somebasic passive circuits designed with S-CPWs and characterized up to 110 GHz are presented invarious CMOS technologies. The low insertion losses and relative low surfaces of a powerdivider and a passband filter show the great interest of S-CPW to integrate compact passivecircuits in classical CMOS technologies at millimeter-wave frequencies. Guide coplanaire à ondes lentes Filtres Diviseur de puissance Circuits intégrés CMOS Forts facteur de qualité Slow-wave coplanar waveguides Filters Power splitters CMOS integrated circuits High quality factor
65	Three Dimensional Direct Print Additively Manufactured High-Q Microwave Filters and Embedded Antennas Hawatmeh, Derar Fayez 28 March 2018 (has links) The need for miniaturized, and high performance microwave devices has focused significant attention onto new fabrication technologies that can simultaneously achieve high performance and low manufacturing complexity. Additive manufacturing (AM) has proven its capability in fabricating high performance, compact and light weight microwave circuits and antennas, as well as the ability to achieve designs that are complicated to fabricate using other manufacturing approaches. Direct print additive manufacturing (DPAM) is an emerging AM process that combines the fused deposition modeling (FDM) of thermoplastics with micro-dispensing of conductive and insulating pastes. DPAM has the potential to jointly combine high performance and low manufacturing complexity, along with the possibility of real-time tuning. This dissertation aims to leverage the powerful capabilities of DPAM to come-up with new designs and solutions that meet the requirements of rapidly evolving wireless systems and applications. Furthermore, the work in this dissertation provides new techniques and approaches to alleviate the drawbacks and limitations of DPAM fabrication technology. Firstly, the development of 3D packaged antenna, and antenna array are presented along with an analysis of the inherent roughness of 3D printed structures to provide a deeper understanding of the antenna RF performance. The single element presents a new volumetric approach to realizing a 3D half-wave dipole in a packaged format, where it provides the ability to keep a signal distribution network in close proximity to the ground plane, facilitating the implementation of ground connections (e.g. for an active device), mitigating potential surface wave losses, as well as achieving a modest (10.6%) length reduction. In addition, a new approach of implementing conformal antennas using DPAM is presented by printing thin and flexible substrate that can be adhered to 3D structures to facilitate the fabrication and reduce the surface roughness. The array design leverages direct digital manufacturing (DDM) technology to realize a shaped substrate structure that is used to control the array beamwidth. The non-planar substrate allows the element spacing to be changed without affecting the length of the feed network or the distance to the underlying ground plane. The second part describes the first high-Q capacitively-loaded cavity resonator and filter that is compatible with direct print additive manufacturing. The presented design is a compromise between quality factor, cost and manufacturing complexity and to the best of our knowledge is the highest Q-factor resonator demonstrated to date using DPAM compatible materials and processes. The final version of the single resonator achieves a measured unloaded quality factor of 200-325 over the frequency range from 2.0 to 6.5 GHz. The two pole filter is designed using a coupled-resonator approach to operate at 2.44 GHz with 1.9% fractional bandwidth. The presented design approach simplifies evanescent-mode filter fabrication, eliminating the need for micromachining and vias, and achieving a total weight of 1.97 g. The design is fabricated to provide a proof-of-principle for the high-Q resonator and filter that compromises between performance, cost, size, and complexity. A stacked version of the two-pole filter is presented to provide a novel design for multi-layer embedded applications. The fabrication is performed using an nScrypt Tabletop 3Dn printer. Acrylonitrile Butadiene Styrene (ABS) (relative permittivity of 2.7 and loss tangent of 0.008) is deposited using fused deposition modeling to form the antenna, array, resonator, and filter structures, and Dupont CB028 silver paste is used to form the conductive traces conductive regions (the paste is dried at 90 °C for 60 minutes, achieving a bulk DC conductivity of 1.5×106 S/m.). A 1064 nm pulsed picosecond Nd:YAG laser is used to laser machine the resonator and filter input and output feedlines. 3D-printing Dipole Picosecond laser machining Quality factor Array Non-planar Capacitively-loaded cavity Evanescent-mode Stacked structure Vertically Coupled Electrical and Computer Engineering Electromagnetics and Photonics
66	Factor Investing on the Swedish Stock Market : A Quantitative Study of a Model Based on Quality and Value Adolfsson, Teodor, Domellöf, Henrik January 2018 (has links) Investors and fund managers have, since the start of financial markets, always been on the lookout for new ways of beating the market. However, researchers of the Efficient Market Hypothesis have shown that markets are usually highly efficient, implying that there are few possibilities of earning returns that are higher than the market returns, on a risk adjusted basis. Prevailing theories, such as the Capital Asset Pricing Model, has shown that increased return must stem from taking on higher risk. Though, this model’s explanatory power has been challenged by numerous researchers who propose different factors, other than market risk, which could hold explanatory power when it comes to returns in the stock market. This area of research is called factor investing, and has shown that factors such as momentum, size, and value, all can lead to outperforming the market.This study examines how a model based on two common factors, quality and value, would have performed on the Swedish stock market. The study is based on five portfolios chosen by the quality and value factors, each one held for 5 years, examined over a 25-year time span and uses the capital asset pricing model as a tool to measure whether or not the selected factors outperform the market. The study has taken a quantitative approach to examining the research question, using a positivistic and objectivistic view.The results of the study show evidence that the quality and value factors can lead to significant outperformance relative to the market index. Both total returns and risk adjusted returns were higher than the market index for some of the portfolios created using the quality and value factors. Furthermore, statistical evidence was found of that CAPM not fully explains all returns, and thus, that the returns are in part explained by the quality and value factors. The findings led to the conclusion that the quality and value factors does, in fact, hold explanatory power beyond that of CAPM. Purchasing quality companies at a reasonable price is shown to be a sound investment strategy, and that a portfolio created using the quality and value factors has good chances of outperforming the market index. Factor Investing Quality Factor Value Factor ROE Earnings Yield Efficient Market Hypothesis Capital Asset Pricing Model Swedish Stock Market Business Administration Företagsekonomi
67	De l'influence des paramètres mécaniques et électroniques sur l'efficacité de la résonance d'un wafer de silicium encastré par effet photo-thermo-acoustique / Influence of carrier lifetime and thickness for photo-thermally induced mechanical resonance of clamped silicon wafers Chapus, Carine 30 June 2010 (has links) L'influence de l'épaisseur et de la durée de vie des porteurs sur l'efficacité de la mise en résonance d'une membrane clipsée de silicium excitée par effet photo-thermo-acoustique a été étudiée. Pour cela, nous avons modélisé les phénomènes physiques spécifiques aux semi conducteurs mis en jeu afin de connaître leur influence sur la vibration créée pour augmenter l'efficacité de la conversion photo-acoustique. Un modèle analytique du mode d'encastrement de la membrane a également été développé. Puis, un banc expérimental utilisant une diode laser pour l'excitation lumineuse et un vibromètre optique pour la détection des déplacements induits a été conçu pour obtenir la réponse en fréquence de membranes de différentes épaisseurs (de 100 à 3000µm) et durées de vie de porteurs (de 1 à 45µs). Ces essais ont montré un décalage vers les basses fréquences d'environ 1kHz de la fréquence du premier mode de résonance et une faible valeur du facteur de qualité de l'ordre de la dizaine dus au choix de l'encastrement par serrage des wafers de silicium à l'aide de joints toriques en nitrile dans l'air. Cette étude a permis de montrer que, dans nos conditions expérimentales, le facteur de qualité était optimal pour une valeur particulière de l'épaisseur de membrane de l'ordre de 300µm par l'effet combiné de la pression extérieure de l'air ambiant et des pertes dans ce type d'encastrement. L'augmentation de la durée de vie des porteurs n'a pas d'effet sur le facteur de qualité alors qu'il semble faire augmenter légèrement l'amplitude de la résonance. / The influence of mechanical housing conditions and electronic properties of clamped silicon wafers in resonance configuration induced by photo-thermal-acoustic effect is studied. First, we have modelised the specific physical phenomena involved in semiconductors in order to increase the efficiency of the photo-acoustic conversion. A simplified model of clamped membrane has also been developed. Next,, an experimental set up to observe this phenomenon and to obtain the frequency response of the membrane has been built to test numerous silicon wafers with thickness from 100 to 3000µm and carrier life time between 1and 45µs. These tests showed a shift to lower frequency of about 1 kHz of the first resonance mode frequency and a low quality factor value of the order of ten due to our choice of soft clamping of silicon wafers using Nitrile O-ring in air. With our experimental conditions, the quality factor was found optimal for a thickness value of about 300µm due to the combined effects of mounting and air losses. The increase of carrier lifetime does not change the quality factor but seems to slightly increase the resonance amplitude. Photo-thermo-acoustique Membrane de silicium Résonance Efficacité Facteur de qualité Durée de vie de porteurs Photo-thermo-acoustic Silicon membrane Resonance Efficiency Quality factor Lifetime
68	Capteurs passifs à ondes élastiques de surface sans fil pour mesure paramétrique sur une gamme de température étendue (25 / 650ºC) / Wireless and passive surface acoustic wave sensors for physical parameter measurement in an extended temperature band (25/560°C) Francois, Bruno 24 May 2013 (has links) Les travaux visant au développement de capteurs passifs interrogeables sans fil pour sonder des températures supérieures à 600 °C s’inscrivent dans le projet européens SAWHOT. Des capteurs à ondes élastiques de surface sont modélisés, réalisés et caractérisés par une liaison radiofréquence. Le paramètre physique mesuré par ce capteur est la température, avec une mesure au-delà de 900°Cpour les applications de maintenance préventive des turbines à combustion ou pour le contrôle de procédés dans les fours de synthèse de nano-tubes de carbone. Les substrats piezoélectriques standards tels que le quartz ou le niobate de lithium ne sont pas envisageables : l’ensemble de ces travaux s’articule autour de la langasite, substrat piezoélectrique opérant jusqu’à 1470°C et ne présentant aucune température de transition (température de Curie) jusqu’à sa température de fusion située à 1470°C. Compte tenu de la vitesse des ondes élastiques de surface des coupes considérés et également des limitations imposées par les moyens de réalisations technologiques, ces résonateurs sont mesurés sans fil à une fréquence proche de la bande ISM centré en 434 MHz. Les dispositifs ainsi réalisés ont été encapsulés via une procédure innovante de mise en boîtier qui permet alors la mesure de capteurs à ondes élastiques de surface dans des environnements où la température dépasse 700°C. De nombreuses études expérimentales ont alors été menés dans le but d’évaluer les performances des capteurs à ondes élastiques de surface en terme de bilan de liaison radiofréquence, reproductible de la mesure, vieillissement au cours des cycles en températures / Development of wireless passive sensor for temperature measurement above 600°C has been performed in the frame of the European SAWHOT project. In this context, surface acoustic wave sensors have been designed, fabricated and characterized by radiofrequency measurement. Physical parameter measured by these sensors is the temperature, reaching values up to 900°C for monitoring in combustion engines andIn ovens used for carbon nano-tubes growth. In order to measure temperature in harsh environments, classical piezoelectric substrates are not usuable: langasite substrate has been considered as a favorable option since it exhibits no transition temperature and is able to operate until its exhibits no transition temperature and is able to operate until its melting temperature, at 1470 °C. regarding the parameters of the surface acoustic waves and the limitation of the fabrication process and devices, the resonators are measured wirelessly in the ISM band centered at 434 MHz (3μm of interdigital transducer period and a transducers with of 1μm). Two main manufacturing technologies are considered, stepper and nano-imprint technologies. The fabricated devices have been packaged by using an innovative process protecting the devices and allowing fir wireless measurements until 700°C. Multiple experiments have been performed in order to characterize the radiofrequency link between the reader and the sensor, the reproducibility of the measurement, the aging effect on the response of the device after high temperature cycles. Capteurs Haute temperature Résonateurs Ondes élastiques de surface Transducteur Couplage électromécanique Facteur de qualité Oscillateurs Sensors High temperature Resonators Surface acoustic wave Transducer Electromechanical coupling Quality factor Oscillators 621.36
69	Koincidenční detektor FM - laboratorní přípravek / FM Coincidence Detector - Laboratory Equipment Mlčoch, Jiří January 2009 (has links) This work is aimed at an analysis of frequency demodulation, design, simulation, and construction of a coincidence demodulator. Chapter 1 explains the basic characteristics of frequency modulated (FM) signals and provides an overview of the required signal bandwidth, the signal spectrum, and the signal-to-noise ratio after demodulation. Chapter 2 describes each type of FM demodulator separately, and it includes all significant types of demodulator for FM radio broadcast. The function of the coincidence demodulator and its characteristics are explained in detail. Chapter 3 contains a theoretical solution of the phase shift network. Calculated values of the circuit elements are verified by simulation with a view to the total harmonic distortion of the demodulator output signal. Chapter 4 describes the front-end circuit of the receiver. Here, the filter design and the mixer circuit description are provided. The final part of the thesis presents the applicable laboratory task.
70	Návrh řiditelných diferenčních filtrů s proudovými aktivními prvky / Design of adjustable fully-differential filters with current active elements Polášek, Lubomír January 2010 (has links) The master thesis deals with design of the fully differential frequency filters working in the current mode and is focused on possibilities of the natural frequency and the quality factor adjustment. At the beginning, there is a brief description of frequency filters and active elements (MO-CF, FD-CF and DACA), which are used in the thesis. Furthermore, simplified signal flow graphs design method and transformation of passive and active elements to the differential structures are described. The designs of four differential circuitries which provide possibility of tuning the natural frequency or quality factor by the gain of the DACA element are shown in the thesis. Simulation results made in OrCAD program with help of third-order models are included. The practical implementation of the differential frequency filter for tuning of the natural frequency by the DACA elements is shown in the last chapter.

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