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31	Design trade-off of low power continuous-time [Sigma Delta] modulators for A/D conversions Song, Tongyu. January 1900 (has links) Thesis (Ph. D.)--University of Texas at Austin, 2007. / Vita. Includes bibliographical references.
32	Conversor digital quaternario para analogico / Quaternary digital to analog converter Silva, Jose Carlos da 28 February 2005 (has links) Orientador: Alberto Martins Jorge / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Engenharia Eletrica e de Computação / Made available in DSpace on 2018-08-04T16:28:44Z (GMT). No. of bitstreams: 1 Silva_JoseCarlosda_D.pdf: 8074106 bytes, checksum: 2f71934ce780079124988d97ff4b0521 (MD5) Previous issue date: 2005 / Resumo: Neste trabalho é apresentada a lógica múltiplo valor como opção para substituir ou ser usada como interface com a lógica binária. A lógica múltiplo valor difere da lógica binária clássica devido ao fato que os seus dígitos estão além de zeros e uns. Utilizando a lógica múltiplo valor consegue-se comunicação em entre blocos ou com o mundo externo a um chip com menor número de interconexões, o que acarretará a diminuição da área do circuito integrado e redução de custos. Pesquisadores e industria caminham para a pesquisa e desenvolvimento de circuitos múltiplos valores, que podem substituir ou ser utilizados como interface com os circuitos de dois valores (binários). Este trabalh o apresenta o desenvolvido do projeto de um conversor digital quaternário para analógico que tem quatro entradas e resolução equivalente a um conversor digital binário para analógico de oito entradas. Este conversor foi confeccionado totalmente em tecnologia CMOS 0.35µm, tendo como resultado um protótipo de um circuito integrado múltiplo valor que contém todas as células de um conversor digital binário para analógico. Este conversor apresenta consumo de potência abaixo de 1mW, alimentação simples de 5V e compactação (900µm x 235µm) / Abstract: In this work is presented the multiple value logic as option to substitute or to be used as interface with the binary logic. The multiple value logic differs of the classic binary logic to the fact that its digits are beyond zeros and ones. Using the multiple logic value obtains communication in between blocks or with the external world to one chip with lesser number of interconnections, what it will cause the reduction of the area of the integrated circuit and reduction of costs. Researchers and industry walk for the research and development of multiple values circuits, that can substitute or be used as interface with the circuits of two values (binary). This work presents the developed one of the project of a quaternary digital to analog converter that it has four inputs and resolution equivalent to a binary digital to analog converter of eight inputs. This converter was confectioned totally in technology CMOS 0.35µm, having as resulted an prototype of an integrated circuit multiple value that contains all the cells of a binary digital to analog converter. This converter presents consumption of power below of 1mW, simple voltage of 5V and compacting (900µm x 235µm) / Doutorado / Eletrônica, Microeletrônica e Optoeletrônica / Doutor em Engenharia Elétrica Lógica a multiplos valores Circuitos integrados Conversores digitais-analogicos Multiple value logic Integrated circuits e Digital to analog converters
33	Discrete-time crossing-point estimation for switching power converters Smecher, Graeme. January 2008 (has links) No description available. Analog-to-digital converters. Digital-to-analog converters.
34	Variable speed constant frequency power conversion with permanent magnet synchronous and switched reluctance generators Rim, Geun-hie 20 October 2005 (has links) Power electronics is inevitably concerned with the processing of variable speed power generations such as in wind turbines, aircraft systems and naval on-board ship systems. The nature of these types of energy is distinct in that their frequency and power vary depending on the speed of the prime-mover. To make use of the variable speed energy, a power processing scheme which transforms the variable speed energy into a constant frequency power is required. There are measures such as mechanical and electrical links for such purposes. Electrical link systems are chosen in this study due to their fast responses and high reliabilities. The power conversion stage may be a dc link with a line-commutated converter, a dc link with a self-commutated inverter, or a cycloconverter. The line-commutated converter and cycloconverter power stages require a fixed frequency supply for operation whereas the self-commutated inverter is capable of stand-alone operation, thus making it attractive. Two cases of variable speed power generation using a permanent magnet synchronous machine (hereafter referred to as PMSM) and a switched reluctance machine (hereafter referred to as SRM) were studied in this dissertation. The possible use of PMSMs has been proved by the good correlation between the experimental results and the theoretically predicted results. Three different control strategies have been proposed, implemented in hardware, and experimentally verified. The efficiency of the VSCF power conversion with a self commutated converter were comparable to the one using a line-commutated converter. A novel converter topology with no dc link capacitor has been proposed for the application of SRMs to the VSCF power conversion. The proposed topology directly links the constant frequency ac source to the SRM. This feature enhances the reliability of the power conversion scheme and reduces the weight and volume of the system. The correlation between the theoretical and experimental results of some key issues showed the feasibility of the proposed VSCF power conversion scheme. In the course of the study, one stage ac to dc power conversion with a compact transformer was required for dc loads. However, phase-controlled ac to dc conversion has the disadvantages of low power factor and harmonic pollution on the utility side, particularly in the case where dc voltage regulation is required. Therefore, a novel single phase rectifier for dc load which provides ohmic isolation with a high frequency transformer is extensively investigated. The proposed scheme had a wide output variation on dc output while maintaining unity power factor and sinusoidal current in the ac input side. Three control strategies for the operation of the converter were proposed and verified experimentally. The harmonic spectra on ac and dc sides are analytically derived and experimentally proved under some load conditions. / Ph. D. LD5655.V856 1992.R55 Digital-to-analog converters Pulse-duration modulation Switching theory -- Mathematical models Variable speed drives
35	Low-power high-linearity digital-to-analog converters Kuo, Ming-Hung 09 March 2012 (has links) In this thesis work, a design of 14-bit, 20MS/s segmented digital-to-analog converter (DAC) is presented. The segmented DAC uses switched-capacitor configuration to implement 8 (LSB) + 6 (MSB) segmented architecture to achieve high performance for minimum area. The implemented LSB DAC is based on quasi-passive pipelined DAC that has been proven to provide low power and high speed operation. Typically, capacitor matching is the best among all integrated circuit components but the mismatch among nominally equal value capacitors will introduce nonlinear distortion. By using dynamic element matching (DEM) technique in the MSB DAC, the nonlinearity caused by capacitor mismatch is greatly reduced. The output buffer employed direct charge transfer (DCT) technique that can minimize kT/C noise without increasing the power dissipation. This segmented DAC is designed and simulated in 0.18 μm CMOS technology, and the simulated core DAC block only consumes 403 μW. / Graduation date: 2012 DAC data converter digital to analog converter direct charge transfer DCT Pipeline dynamic element matching
36	Design of switched-current circuits for a bandpass delta-sigma modulator Manapragada, Praveen 27 April 1995 (has links) Graduation date: 1996
37	Oscillation Control in CMOS Phase-Locked Loops Terlemez, Bortecene 22 November 2004 (has links) Recent advances in voltage-controlled oscillator (VCO) design and the trend of CMOS processing indicate that the oscillator control is quickly becoming one of the forefront problems in high-frequency and low-phase-noise phase-locked loop (PLL) design. This control centric study explores the limitations and challenges in high-performance analog charge-pump PLLs when they are extended to multiple gigahertz applications. Several problems with performance enhancement and precise oscillator control using analog circuits in low-voltage submicron CMOS processes, coupled with the fact that analog (or semi-digital) oscillators having various advantages over their digitally controlled counterparts, prompted the proposal of the digitally-controlled phase-locked loop. This research, then, investigates a class of otherwise analog PLLs that use a digital control path for driving a current-controlled oscillator. For this purpose, a novel method for control digitization is described where trains of pulses code the phase/frequency comparison information rather than the duration of the pulses: Pulse-Stream Coded Phase-Locked Loop (psc-PLL). This work addresses issues significant to the design of future PLLs through a comparative study of the proposed digital control path topology and improved cutting-edge charge-pump PLLs. Charge pump PLL Phase-locked loops Mixed-signal circuits Voltage-controlled oscillators Digital electronics Digital-to-analog converters
38	Design trade-off of low power continuous-time [Sigma Delta] modulators for A/D conversions Song, Tongyu 29 August 2008 (has links) The research investigates several critical design issues of continuous-time (CT) [Sigma Delta] modulators. The first is to investigate the sensitivity of CT [Sigma Delta] modulators to high-frequency clock spurs. These spurs down-convert the high-frequency quantization noise, degrading the dynamic range of the modulator. The second is to study the robustness of continuous-time loop filters under large RC product variations. Large RC variations in the CMOS process strongly degrade the performance of continuous-time [Sigma Delta] modulators, and reduce the production yield. The third is to model the harmonic distortion of one-bit continuous-time [Sigma Delta] modulators due to the interaction between the first integrator and the feedback digital-to-analog converter (DAC). A closed-form expression of the 3'rd-order harmonic distortion is derived and verified. Conventional CT [Sigma Delta] modulators employ all active integrators: each integrator needs an active amplifier. The research proposes a 5th-order continuous-time [Sigma Delta] modulator with a hybrid active-passive loop filter consisting of only three amplifiers. The passive integrators save power, and introduce no distortion. The active integrators provide gain and minimize internal noise contributions. A single-bit switched-capacitor DAC is employed as the main feedback DAC for high clock jitter immunity. An additional current steering DAC stabilizes the loop with the advantage of simplicity. To verify the proposed techniques, a prototype continuous-time [Sigma Delta] modulator with 2-MHz signal bandwidth is designed in a 0.25-¹m CMOS technology targeting for GPS or WCDMA applications. The experimental results show that the prototype modulator achieves 68-dB dynamic range over 2-MHz bandwidth with a 150-MHz clock, consuming 1.8 mA from a 1.5-V supply. Digital-to-analog converters Integrators Continuous-time filters Phase distortion (Electronics)
39	STUDIES ON HIGH-SPEED DIGITAL-TO-ANALOG CONVERSION Balasubramanian, Sidharth January 2013 (has links) No description available. Electrical Engineering
40	Low-power ASIC design with integrated multiple sensor system Jafarian, Hossein 08 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / A novel method of power management and sequential monitoring of several sensors is proposed in this work. Application specific integrated circuits (ASICs) consisting of analog and digital sub-systems forming a system on chip (SoC) has been designed using complementary metal-oxide-semiconductor (CMOS) technology. The analog sub-system comprises the sensor-drivers that convert the input voltage variations to output pulse-frequency. The digital sub-system includes the system management unit (SMU), counter, and shift register modules. This performs the power-usagemanagement, sensor-sequence-control, and output-data-frame-generation functions. The SMU is the key unit within the digital sub-system is that enables or disables a sensor. It captures the pulse waves from a sensor for 3 clocks out of a 16-clock cycle, and transmits the signal to the counter modules. As a result, the analog sub-system is at on-state for only 3/16th fraction (18 %) of the time, leading to reduced power consumption. Three cycles is an optimal number selected for the presented design as the system is unstable with less than 3 cycles and higher clock cycles results in increased power consumption. However, the system can achieve both higher sensitivity and better stability with increased on-state clock cycles. A current-starved-ring-oscillator generates pulse waves that depend on the sensor input parameter. By counting the number of pulses of a sensor-driver in one clock cycle, a sensor input parameter is converted to digital. The digital sub-system constructs a 16-bit frame consisting of 8-bit sensor data, start and stop bits, and a parity bit. Ring oscillators that drive capacitance and resistance-based sensors use an arrangement of delay elements with two levels of control voltages. A bias unit which provides these two levels of control voltages consists of CMOS cascade current mirror to maximize voltage swing for control voltage level swings which give the oscillator wider tuning range and lower temperature induced variations. The ring oscillator was simulated separately for 250 nm and 180 nm CMOS technologies. The simulation results show that when the input voltage of the oscillator is changed by 1 V, the output frequency changes linearly by 440 MHz for 180 nm technology and 206 MHz for 250 nm technology. In a separate design, a temperature sensitive ring oscillator with symmetrical load and temperature dependent input voltage was implemented. When the temperature in the simulation model was varied from -50C to 100C the oscillator output frequency reduced by 510 MHz for the 250 nm and by 810 MHz for 180 nm CMOS technologies, respectively. The presented system does not include memory unit, thus, the captured sensor data has to be instantaneously transmitted to a remote station, e.g. end user interface. This may result in a loss of sensor data in an event of loss of communication link with the remote station. In addition, the presented design does not include transmitter and receiver modules, and thus necessitates the use of separate modules for the transfer of the data. Low-power Asic design. Multiple sensor system Digital electronics Sensor networks Voltage-controlled oscillators Integrated circuits Analog-to-digital converters Digital-to-analog converters

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