Global ETD Search

1	Design of Monolithic Step-Up DC-DC Converters with On-Chip Inductors Hasan, Ayaz 26 August 2011 (has links) This thesis presents the design of a step-up DC-DC converter with on-chip coupled inductors. Circuit theory of DC-DC converters in general is presented, after which a mathematical model of a step up converter is developed. A circuit implementation optimized from results of the mathematical model follows. For a completely integrated step-up converter, the inductor size is reduced by increasing the frequency of operation and using a circuit topology that employs coupled inductors. Spiral inductors are also studied to achieve maximum quality factor and inductance. A fast PWM control system is used to regulate the high-frequency converter. The fabrication was done in standard TSMC 0.18-$\mu$m digital CMOS process for four circuits, including one with a conventional topology and the others with a coupled inductor topology with varying inductor geometries. Measurement results from a fabricated prototype have been presented, demonstrating the functionality of the four circuits with coupled inductors on the fabricated chip and the improvement of the coupled solution over the conventional design. It is demonstrated that the circuits with coupled inductors have a significant improvement in performance based on conversion ratio and efficiency. Finally, the design process is evaluated and recommendations are made for future work. Furthermore, a new self-oscillating and robust control system is proposed that enables simpler and more efficient regulation for high-frequency converters such as one developed for this thesis. DC-DC Converter Step-Up Converter On-Chip Inductors
2	Two-Phase Boost Converter Gunawan, Tadeus 01 December 2009 (has links) A boost converter is one of the most efficient techniques to step up DC input voltage to a higher needed DC output voltage. The boost converter has many possible applications, such as in a photovoltaic system, hybrid car and battery charger. The proposed prototype in this report is a proof of concept that a Two-Phase Boost Converter is a possible improvement topology to offer higher efficiency without compromising any advantages readily offered by a basic boost. The prototype is designed to be able to handle up to 200 watts of output power with an input of 36 volts and an output of 48 volts. This paper goes through step-by-step the calculation, design, build and test of a Two-Phase Boost Converter. Calculations found in this paper were done on Mathcad and the simulations were done on LTSpice and Pspice. These include converter’s efficiency and other measures of converter’s performance. Advantages, disadvantages as well as possible improvements of the proposed topology will be presented. Data collected and analyzed from the prototype were done on a bench test, not through an actual application. Two-phase Boost Converter Frequency multiplication Step-up converter DC-DC Converter
3	UHF energy harvester in CMOS technology Michelon, Dino 26 April 2016 (has links) Un des défis majeurs de l’Internet des Objets et, plus généralement, des tous les réseaux de capteurs sans fils, c’est l’alimentation de chaque nœud connecté. La solution la plus commune est d’équiper chaque dispositif d’une batterie mais cela introduit plusieurs contraintes, qui mettent en question la faisabilité de cette approche sur le long terme (durée de vie limité, couts de gestion élevé, empreinte écologique).Cette thèse développe une possible solution basée sur la transmission sans-fils de l’énergie. Un récupérateur d’énergie RF, composé d’une antenne, un redresseur haute-fréquence et un convertisseur élévateur, est présenté. Ce système permet de récupérer les ondes électromagnétiques et de produire une tension continue en sortie, qui peut être utilisé pour alimenter des microcontrôleurs ou des capteurs. L’absence d’une batterie interne augmente la flexibilité globale, surtout pour les situations où le remplacement n’est pas possible (ex. dispositifs implantés, nombre élevé de nœuds, milieux dangereux). Une étude approfondie sur les redresseur intégrés ultra-haute-fréquence de type Schottky et MOS a été mené ; plusieurs topologies ont été analysées et optimisées. De plus, l’utilisation d’un convertisseur élévateur a été envisagée, dans le but d’accroitre la tension en sortie ; une première version discrète et puis une plus compacte version intégrée, ont été abordées et testées. Ces développements ont permis d’aboutir à un récupérateur complet, potentiellement capable d’alimenter un microcontrôleur du commerce. / One of the challenges of the Internet of Things and, more in general, of every wireless sensor network is to provide electrical power to every single one of its smart nodes. A typical solution uses batteries but various major concerns reduce the long-term feasibility of this approach (limited lifetime, maintenance and replacement costs, and environmental footprint).This thesis develops a possible solution based on the wireless transmission of power. A complete RF harvester composed of an antenna, a UHF rectifier and a step-up voltage converter is presented. This system captures electromagnetic waves and converts them to a stable DC voltage to supply power to common logic circuits like microcontrollers and sensors. The lack of an internal battery provides an extended flexibility, especially when its replacement is not a viable option (ex. implanted devices, large number of nodes, dangerous environments, etc.). An in-depth study of integrated Schottky and CMOS UHF rectifiers is carried out; various topologies and optimizations are analyzed. Moreover, the use of an additional step-up converter is proposed in order to increase the system output voltage; an early discrete implementation and a final, more compact, integrated version are discussed and tested. These developments lead to a complete system capable of potentially powering an application with an off-the-shelf microcontroller. Récupération d’énergie Transmission sans-Fils de l’énergie Rectenna Redresseur UHF Convertisseur élévateur Rfid Réseau de capteurs Internet des Objets Energy Harvesting Wireless Power Transfer Rectenna UHF Rectifier Step-Up Converter Rfid Wireless Sensor Network Internet of Things
4	Řízený zdroj napětí a proudu připojitelný přes USB / USB controlled voltage and current source Pytela, Ondřej January 2015 (has links) This diploma thesis is focused on complete construction of lab source which is controlled and powered by USB in personal computer. Different types of possible solutions are mentioned and finally one of them has been picked up as a best choice, which is developed in the rest of this thesis. Besides hardware construction there is also shown creation of main program for PIC18F14K50 microcontroller and main application that provides controlling of USB source via personal computer.
5	Modely stejnosměrných tranzistorových měničů v programu Simulink / Models of DC transistor converters in Simulink program Loup, Martin January 2020 (has links) The master’s thesis is focused on the creation of models of DC/DC converters and control program for input parameters and their configuration. The first part is theoretical and she is dedicated to the description of the program Matlab. The second chapter is dedicated to DC/DC converters. Their function is described there and the necessary equations for the design are derived. All of this is complemented by the calculation of line losses in semiconductor elements and the design of voltage and current regulator. The last two parts deal with the description of the created models in Simulink and control program in a graphical environment. The created program is able to edit and recalculate parameters of the converters, calculate line losses on semiconductor components, perform a model simulation or open it.

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