Global ETD Search

21	Summer-Less Dual Charge Pump Based PLL With Wide Lock Range Using Analog Frequency Detector Raghavendra, R G 10 1900 (has links) Phase Locked Loop (PLL) is an integral component of clock generation circuits. A third order Charge Pump PLL (CPPLL) is most widely employed PLL architecture due to its zero steady state phase error. A monolithic implementation of such a CPPLL presents numerous challenges to PLL designers, the number of such challenges vary depending on the process technology employed and the end application. One such challenge that is worth mentioning is the on-chip integration of the second order passive loop filter. The area occupied by the second order passive loop filter is mainly determined by the zero determining capacitance (CZ). A low loop bandwidth CPPLL has a higher CZ value, and hence consumes a larger die area than a large loop bandwidth CPPLL. Literature survey shows that the problem of higher CZ value in low loop bandwidth CPPLL is addressed by using some form of emulation techniques. A relatively simpler emulation technique is the use of dual charge pump based loop filter. Existing dual charge pump based loop filter consume extra elements (such as summer that need opamps to realize the summer function) for achieving low CZ value. These extra elements consume extra area and additional power. We present two types of Summer-Less Dual Charge Pump (SDCP) based loop filter designs that do not need extra elements and still achieves low CZ value and this is achieved by using a second charge pump in an appropriate way. A test chip was implemented in 0.13µm UMC MMRFCMOS process to verify the presented circuits. The presented SDCP based loop filter circuits are particularly useful in designs employing multiple CPPLL’s and design employing low loop bandwidth CPPLL’s. Another challenge worth-mentioning is the frequency ranges over which the PLL can be locked. The Voltage Controlled Oscillator (VCO) of PLL mainly determines the frequency locking range of a PLL. A typical VCO has a frequency locking range of usually 1:2 to 1:3. The VCO frequency tuning range reduces with reduction in supply voltage. This poses a serious problem in low supply voltage applications that demand a wide frequency locking range, sometimes greater than 1:3. We have addressed this problem of wide PLL lock range, by using an Analog Frequency Detector. A wide frequency lock range is achieved, either by dynamically modifying the VCO or the feedback divider of PLL. Both the approaches are equally feasible. The frequency detector is used for dynamically modifying the VCO or the feedback divider of PLL. Two test chips were implemented to verify the presented Analog Frequency Detector scheme. A testchip implemented in 0.25µm CSM analog process achieves wide frequency lock range by dynamically modifying the feedback divider of PLL. Another testchip implemented in 0.13µm UMC MMRFCMOS process achieves wide frequency lock range by dynamically modifying the center frequency of the VCO. Presented analog frequency detection scheme is particularly useful in applications that demand wide PLL lock range from a single die. Special Devices (Computer Engineering) Analog Frequency Detector Charge Pump Phase Locked Loop Phase Locked Loop (PLL) Phase Locked Loop Filters Phase Locked Loop Filter Design Loop Filter Design Computer Engineering
22	Návrh zdvojovače napětí v technologii ACMOS 0,25 m / Voltage doubler design in 0,25 m CMOS technology Synek, Ladislav January 2014 (has links) This diploma thesis deals with the design of a partially integrated charge pump in 0.25 micron technology ACMOS. The work is divided into two main parts, theoretical and practical. The theoretical section describes in detail various topologies of higher voltage generation of a charge pump and selected methods of regulating the output voltage of charge pumps. The practical part deals with the the actual design of a charge pump together with the arguments for the choice of the TPVD topology and the type of the regulation. Three regulation methods of a charge pump were implemented, tested and are dealt with: Pulse Skip, Constant frequency and PWM. There are 3 sub chapters, each describing a different regulation method, defining all the key elements of the design of such a charge pump and the results of the simulations are discussed. Conclusion of the thesis summarizes the results of the design of charge pumps, comparing them on the basis of the chosen type of output voltage regulation.
23	Etude et réalisation d'un récupérateur d'énergie vibratoire par transduction électrostatique en technologie MEMS silicium / Elaboration of a capacitive transducer for vibration-to-electricity power conversion Guillemet, Raphaël 02 October 2012 (has links) Une solution pertinente afin d'alimenter des capteurs isolés consiste à récupérer l'énergie disponible dans leur environnement immédiat. Parmi les sources d'énergie envisageables, notre choix s'est porté sur les vibrations mécaniques ambiantes. Notre contribution porte sur l'étude et la réalisation, par un procédé de fabrication collective, d'un transducteur électrostatique sans électrets en technologie MEMS Silicium. Nous proposons une étude analytique permettant d'optimiser l'efficacité du générateur électrostatique, tout en considérant une limite sur la tension maximale aux bornes du transducteur afin de ne pas endommager le circuit de conditionnement. Le design proposé prend également en compte d'éventuelles variations de l'amplitude des vibrations externes. Le dispositif a été fabriqué au sein de ESIEE Paris et présente un volume total de moins de 100 mm3.Les tests expérimentaux ont montré un comportement fortement non-linéaire de la structure. Nous avons obtenu une conversion d'énergie mécanique en énergie électrique correspondant à une puissance maximale de 2.3 μW à 260 Hz, pour une accélération de 1 g et à une pression de 0.15 Torr, lorsque le système est pré-chargé avec une tension de 10 V. Une fois implémenté dans un circuit de pompe de charge et pour les mêmes conditions d'accélération et de pression, le système peut fonctionner en complète autonomie pendant plus de 500 secondes pendant lesquelles la puissance délivrée varie de 1.4 μW à 940 nW avec une tension de pré-charge de 10.6 V / A relevant solution to power isolated sensors is to harvest the energy available in their immediate environment. Among the possible sources of energy, our choice was made on ambient mechanical vibrations. We have designed and fabricated a silicon-based and batch-processed MEMS electrostatic transducer which does not use an electret. We present an analytical method to optimize the efficiency of the electrostatic generator, while a voltage limitation on the transducer's terminal is set to prevent any damage in the conditioning electronics. The proposed design also takes into account some possible variations in the amplitude of external vibration. The device was fabricated in ESIEE Paris and its volume is less than 100 mm3. The device was tested experimentally and exhibits a strong non-linear behavior. We obtained a conversion of mechanical energy into electrical energy corresponding to a power of 2.3 μW at 260 Hz, with an acceleration of 1 g and a pressure of 0.15 Torr, when the system is pre-charged with a voltage of10 V. When the device is implemented in a charge pump circuit and under the same parameters of acceleration and pressure, the system can operate in autonomous mode for more than 500 seconds during which the output power varies from 1.4 μW to 940 nW when the pre-charge voltage is 10.6 V Transduction électrostatique Récupération d'énergie Pompe de charge Non-linéarité Micro-technologies Mems Electrostatic transduction Energy harvesting Charge pump Non-linearity Microtechnology Mems
24	Microwave-energy harvesting at 5.8 GHz for passive devices Valenta, Christopher Ryan 27 August 2014 (has links) The wireless transfer of power is the enabling technology for realizing a true internet-of-things. Broad sensor networks capable of monitoring environmental pollutants, health-related biological data, and building utility usage are just a small fraction of the myriad of applications which are part of an ever evolving ubiquitous lifestyle. Realizing these systems requires a means of powering their electronics sans batteries. Removing the batteries from the billions or trillions of these envisioned devices not only reduces their size and lowers their cost, but also avoids an ecological catastrophe. Increasing the efficiency of microwave-to-DC power conversion in energy-harvesting circuits extends the range and reliability of passive sensor networks. Multi-frequency waveforms are one technique that assists in overcoming the energy-harvesting circuit diode voltage threshold which limit the energy-conversion efficiency at low RF input powers typically encountered by sensors at the fringe of their coverage area. This thesis discusses a systematic optimization approach to the design of energy-conversion circuits along with multi-frequency waveform excitation. Using this methodology, a low-power 5.8 GHz rectenna showed an output power improvement of over 20 dB at -20 dBm input power using a 3-POW (power-optimized waveform) compared to continuous waveforms (CW). The resultant efficiency is the highest reported efficiency for low-power 5.8 GHz energy harvesters. Additionally, new theoretical models help to predict the maximum possible range of the next generation of passive electronics based upon trends in the semiconductor industry. These models predict improvements in diode turn-on power of over 20 dB using modern Schottky diodes. This improvement in turn-on power includes an improvement in output power of hundreds of dB when compared to CW. RFID Microwave Rectenna Wireless power transfer Power-optimized waveform Backscatter communication Energy harvesting Charge pump Radio frequency
25	Ultra-low Quiescent Current NMOS Low Dropout Regulator With Fast Transient response for Always-On Internet-of-Things Applications January 2018 (has links) abstract: The increased adoption of Internet-of-Things (IoT) for various applications like smart home, industrial automation, connected vehicles, medical instrumentation, etc. has resulted in a large scale distributed network of sensors, accompanied by their power supply regulator modules, control and data transfer circuitry. Depending on the application, the sensor location can be virtually anywhere and therefore they are typically powered by a localized battery. To ensure long battery-life without replacement, the power consumption of the sensor nodes, the supply regulator and, control and data transmission unit, needs to be very low. Reduction in power consumption in the sensor, control and data transmission is typically done by duty-cycled operation such that they are on periodically only for short bursts of time or turn on only based on a trigger event and are otherwise powered down. These approaches reduce their power consumption significantly and therefore the overall system power is dominated by the consumption in the always-on supply regulator. Besides having low power consumption, supply regulators for such IoT systems also need to have fast transient response to load current changes during a duty-cycled operation. Supply regulation using low quiescent current low dropout (LDO) regulators helps in extending the battery life of such power aware always-on applications with very long standby time. To serve as a supply regulator for such applications, a 1.24 µA quiescent current NMOS low dropout (LDO) is presented in this dissertation. This LDO uses a hybrid bias current generator (HBCG) to boost its bias current and improve the transient response. A scalable bias-current error amplifier with an on-demand buffer drives the NMOS pass device. The error amplifier is powered with an integrated dynamic frequency charge pump to ensure low dropout voltage. A low-power relaxation oscillator (LPRO) generates the charge pump clocks. Switched-capacitor pole tracking (SCPT) compensation scheme is proposed to ensure stability up to maximum load current of 150 mA for a low-ESR output capacitor range of 1 - 47µF. Designed in a 0.25 µm CMOS process, the LDO has an output voltage range of 1V – 3V, a dropout voltage of 240 mV, and a core area of 0.11 mm2. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2018 Electrical engineering charge-pump Dynamic biasing Fast transient response Hybrid biasing NMOS LDO
26	Etude, modélisation et conception d'un multicapteur chimique à base de CNTFET / Study, modeling and design of chemical multisensor based on CNTFET (Carbon NanoTube Field-Effect Transistor) Heitz, Jérôme 19 September 2013 (has links) Depuis quelques années, les explosifs artisanaux à base de peroxyde sont fréquemment utilisés dans les actes de terrorisme. Leur simplicité de conception ne les rend pas moins inoffensifs car ils sont tout aussi puissants que ceux à base de TNT (trinitrotoluène). Au regard des enjeux majeurs de la sécurité globale et en particulier de la protection du citoyen, il devient nécessaire de bénéficier d'instruments de détection fiables. C'est dans ce cadre que s'inscrit ce travail de thèse qui vise à développer un capteur intégré, sensible et sélectif aux traces d'explosifs, notamment ceux à base de peroxyde. Ce nez électronique est constitué d'une matrice de transistors à nanotubes de carbone (CNTFET) et d'une électronique et traitement des données. Après une brève introduction relative aux CNTFET pour la détection gazeuse, nous présentons les bases de l'élaboration d'une modélisation électrique du capteur. Cette modélisation a pour but, à terme, de permettre aux concepteurs decircuits intégrés de bénéficier d'un support de simulation des CNTFET, nécessaire à la mise en oeuvre de l'électronique de contrôle et de conditionnement des signaux. Nous détaillerons également ce qui constitue selon nous l'étape fondamentale précédant l'élaboration d'un modèle compact prédictif basé sur la physique, c'est à dire la compréhension topologique du réseau de nanotubes. Nous détaillerons alors différentes probabilités de contacts entre nanotubes. Nous présentons ensuite,l'élaboration de l'électronique permettant le contrôle des potentiels appliqués aux CNTFET et le conditionnement des signaux électriques. Ce conditionnement a pour objectif d'acheminer les réponses électriques du capteur vers des architectures de traitement de données utilisées pour la détection des différents gaz cibles. L'électronique intégrée en technologie CMOS HV (haute tension) est alimentée par pile basse tension. Des pompes de charge, élévateurs de tension, générant ces hautes tensions ont été étudiées, modélisées et réalisées. Nous proposons également dans ce manuscrit une nouvelle architecture de pompe de charge qui constitue, dans certaines plages d'utilisation, une alternative intéressante aux pompes de charge les plus performantes utilisées jusqu'à présent. / For the last few years, improvised peroxide based explosives are frequently used in acts of terrorism. Their simple design does not make them less threatening than those based on TNT because they are equally as powerful as those based on TNT (trinitrotoluene). In view of the major issues of the overall safety and, in particular, the citizens' protection, it becomes necessary to enjoy reliable detection instruments. Such is the background of this PhD work which aims to develop a built-in sensor,sensitive and selective to traces of explosives, especially those based on peroxide. This electronic nose is made up of a network of carbon nanotube field-effect transistors (CNTFET), and data processing hardware. After a brief introduction relating to CNTFETs for gaseous detection, we will provide the basis for the elaboration of an electronic modeling of the sensor. This modeling aims, at the end, to allow designers of integrated circuits to benefit from a simulation support of CNTFETs, required to the implementation of control and signal conditioning electronics. We will also detail what are the fundamental steps mandatory before the development of a predictive compact model based on physics, which means the topological understanding of the nanotubes network. Then, we will describe different probabilities of contacts between nanotubes. Later, we will introduce the elaboration of the electronics allowing the control of the voltages applied to the CNTFETs and the electrical signals conditioning. The objective of this conditioning is to carry electrical responses from the sensor to data processing architectures used for the detection of the different target gasses. High Voltage CMOS integrated electronics are powered by low-voltage batteries. Charge pumps and voltage boosters which generate these high voltages, have been investigated, modeled and carried out. We also provide in this dissertation a new charge pump architecture which offers, in some ranges of application, an interesting alternative to the most efficient charge pumps used until now. CNTFET Capteur de gaz Modélisation Conception électronique intégrée Pompe de charge CNTFET Gas sensor Modeling Integrated electronics design Charge pump 620.5 621.38
27	Design and fabrication of Mems-based, vibration powered energy harvesting device using electrostatic transduction / Conception et réalisation d'un micro-système pour la récupération de l'énergie vibratoire du milieu ambiant par transduction électrostatique Mahmood Paracha, Ayyaz 11 December 2009 (has links) Avec la réduction de l’énergie consommée par les capteurs miniatures, a émergé le nouveau concept de capteurs autonomes. Il s’agit de capteurs dont l’alimentation ne dépend pas d’une source embarquée de type batterie, dont la durée de vie est limitée. Ils ont en effet la capacité de puiser l’énergie nécessaire à leur fonctionnement à partir de l’environnement dans lequel ils se trouvent. Ce concept présente de nombreux avantages, notamment la diminution des coûts de maintenance des capteurs par l’absence d’une nécessité de remplacement des piles et par conséquent une facilité accrue du déploiement des réseaux de capteurs sans fil. Parmi les sources d’énergie envisageables, les vibrations mécaniques ambiantes comptent parmi les plus prometteuses puisqu’elles sont présentes dans un grand nombre de structures : véhicules, avions, bâtiments, etc. La conversion des vibrations mécaniques en énergie électrique est réalisée en deux étapes. Dans un premier temps, un résonateur mécanique, constitué d’une masse mobile associée à un ressort, est couplé avec les vibrations de l'environnement. Grâce à ce couplage, la masse oscille dans le système de référence et accumule une énergie mécanique. La deuxième étape est la conversion de cette énergie en énergie électrique. Un transducteur électromécanique est le siège d’une force d'amortissement sur la masse en résonance, et effectue donc un travail négatif sur le système mécanique. Notre choix de transducteur électromécanique s’est arrêté sur les transducteurs électrostatiques et piézoélectriques car ils présentent l'avantage d’être compatibilité avec le procédé CMOS et adaptés à la miniaturisation. Nous avons ensuite conçu et fabriqué un transducteur électrostatique utilisant une technologie silicium verre, qui a nécessité le développement d’un procédé ad hoc de gravure DRIE. Le dispositif a été testé en utilisant un circuit électronique de type pompe de charge. Nous avons obtenu une conversion d’énergie mécanique en énergie électrique de 61 nW au moyen d’un dispositif dont la surface est de seulement 66 mm², la sollicitation vibratoire étant à la fréquence de résonance mécanique de la microstructure, qui est de 250 Hz et avec une accélération externe de 0,25 g ainsi qu’une tension initiale de 6V. Le résultat a été confronté avec des simulations effectuées sur la base d’un modèle VHDL-AMS. L’écart avec les mesures est inférieur à 3%. Ce dispositif est le premier convertisseur miniature d’énergie basé sur une transduction électrostatique, fabriqué dans un procédé collectif à base de silicium et sans l'adjonction d'un électret. Afin de procéder à une comparaison pertinente de notre travail avec les autres dispositifs rapportés dans la littérature et qui utilisent la transduction électrostatique, nous proposons une nouvelle figure de mérite (FOM) définie comme une puissance convertie normalisée. Bien que l’état de l’art actuel montre que notre réalisation présente l’un des meilleurs facteurs de mérite, la puissance produite n'est cependant pas suffisante pour alimenter un microsystème réel, à cause notamment d’une tension de « pull-in » trop basse. Quelques pistes d’amélioration sont proposées, notamment l’exploitation de non-linéarités mécaniques pour augmenter la bande passante du spectre énergétique exploitable par le micro-dispositif / Due to size effects, the microtechnologies that are used to manufacture micro-sensors, allowed a drastic reduction of electrical power consumption. This feature contributed to the emergence of the concept of autonomous sensors, which have the ability to take the energy needed for their operation from the environment where they are located. Among the different energy sources, our choice was made on ambient mechanical vibrations. The electromechanical conversion is done within a transducer integrated with a micromechanical structure. In this work, we have designed and fabricated an electrostatic transducer based on silicon-glass technology, which required the development of a dedicated deep etching process. The device was tested experimentally and we have obtained a conversion of mechanical energy into electrical energy, corresponding to a power of 61 nW, with a device whose surface area is only 66 mm². This device is the first miniaturized silicon converter based on electrostatic transduction which does not use an electret Transduction électrostatique Power MEMS Récupération de l'énergie Ipop Pompe de charge Electrostatic transduction Power MEMS Energy harvesting Ipop Charge pump circuit
28	Electrical Equivalent Modeling of the Reverse Electrowetting-on-Dielectric (REWOD) Based Transducer along with Highly Efficient Energy Harvesting Circuit Design towards Self-Powered Motion Sensor Gunti, Avinash 08 1900 (has links) Among various energy harvesting technologies reverse electrowetting-on-dielectric energy harvesting (REWOD) has been proved to harvest energy from low frequency motion such as many human motion activities (e.g. walking, running, jogging etc.). Voltage rectification and DC-DC boosting of low magnitude AC voltage from REWOD can be used to reliably self-power the wearable sensors. In this work, a commercial component-based rectifier and DC-DC converter is designed and experimentally verified, for further miniaturization standard 180 nm CMOS process is used to design the rectifier and the DC-DC boost converter.This work also includes the MATLAB based model for REWOD energy harvester for various REWOD models. In REWOD energy harvesting, a mechanical input during the motion causes the electrolyte placed in between two dissimilar electrodes to squeeze back and forth thereby periodically changing the effective interfacial area, hence generating alternating current. The alternating current is given to the rectifier design. There is no realistic model that has been developed yet for this technique. Thereby, a MATLAB based REWOD model is developed for the realistic simulation of the REWOD phenomenon. In the work, a comparison of different REWOD models such as planar surface, rough surface and porous models are performed demonstrating the variations in capacitance, current and voltage. MATLAB Energy harvester CMOS energy harvesting low-frequency rectifier DC-DC boost converter charge pump
29	Design and fabrication of Mems-based, vibration powered energy harvesting device using electrostatic transduction Mahmood Paracha, Ayyaz 11 December 2009 (has links) (PDF) Due to size effects, the microtechnologies that are used to manufacture micro-sensors, allowed a drastic reduction of electrical power consumption. This feature contributed to the emergence of the concept of autonomous sensors, which have the ability to take the energy needed for their operation from the environment where they are located. Among the different energy sources, our choice was made on ambient mechanical vibrations. The electromechanical conversion is done within a transducer integrated with a micromechanical structure. In this work, we have designed and fabricated an electrostatic transducer based on silicon-glass technology, which required the development of a dedicated deep etching process. The device was tested experimentally and we have obtained a conversion of mechanical energy into electrical energy, corresponding to a power of 61 nW, with a device whose surface area is only 66 mm². This device is the first miniaturized silicon converter based on electrostatic transduction which does not use an electret [SPI] Engineering Sciences [SPI] Sciences de l'ingénieur Electrostatic transduction Power MEMS Energy harvesting Ipop Charge pump circuit
30	Theory of super power saving circuits and configurations for mixed signal CPU for smartcard application / Teori om extremt energisparande kretsar och konfigurationer för mixed signal CPU för smartcard applikation Kleist, Anders January 2004 (has links) <p>Designing an application specific integrated circuit (ASIC) must be starting with careful preparations, otherwise the chip will not be as good as possible. The theoretical studies must cover everything from the chip circuits to the application structure. In mobile applications there is extremely important that the current consumption becomes minimized because the battery power is limited. The power reductions studies must include the most power costing circuits on the chip. When the whole circuit or segments of the circuit is not in use, they must switch fast and simple into another mode that consume nearly none power. This mode is called sleep-mode. If the sleep-mode has very low leakage currents, the lifetime of the application will dramatically increase. </p><p>This report studies the most power costing circuits in smartcard application ASIC. The chip should be used to control a LCD display on the smartcard. The circuits that have been investigated are level shifters, charge pumps and LCD drivers, also sleep-mode configuration possibilities have been investigated. Other small preparing work is also included in the thesis.</p> Electronics charge pump sleep-mode level shifter cholesteric liquid crystal smartcard DC-DC converter MTCMOS display driving assembler voltage doubler low power Elektronik Electronics Elektronik

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