Global ETD Search

61	Millimeter-wave Analog to Digital Converters: Technology Challenges and Architectures Shahramian, Shahriar 14 November 2011 (has links) While data converters have been around for nearly nighty years, mm-wave data converters are still in their infancy. Only recently the 40-GHz sampling barrier was broken with the introduction of the next generation high-speed sampling oscilloscopes. Meanwhile, data communication is the main driving force behind mm-wave data converter development. As with any mm-wave circuit, designers must go beyond simply relying on technology advancement to archives acceptable performance. Careful device and passive modeling is critical and systematic design methodology may o er repeatable and scalable mm-wave designs. In this thesis the design methodology and architectural challenges of mm-wave ADCs are explored. Some of the fundamental mm-wave ADC building blocks such as track and hold ampli ers, data distribution networks and ip- ops are implemented in SiGe BiCMOS and CMOS technologies and characterized. Several record breaking circuits are presented along with systematic design methodology. The impact of these circuit blocks on the performance of the next generation ADCs is studied and experimentally veri ed using a 35-GS/s, 4-bit ADC-DAC chain implemented in a SiGe BiCMOS technology. Analog to Digital Converter mm-Wave Circuit Track and Hold Amplifier SiGe CMOS Data Converter TIALA Retimer 0544
62	Millimeter-wave Analog to Digital Converters: Technology Challenges and Architectures Shahramian, Shahriar 14 November 2011 (has links) While data converters have been around for nearly nighty years, mm-wave data converters are still in their infancy. Only recently the 40-GHz sampling barrier was broken with the introduction of the next generation high-speed sampling oscilloscopes. Meanwhile, data communication is the main driving force behind mm-wave data converter development. As with any mm-wave circuit, designers must go beyond simply relying on technology advancement to archives acceptable performance. Careful device and passive modeling is critical and systematic design methodology may o er repeatable and scalable mm-wave designs. In this thesis the design methodology and architectural challenges of mm-wave ADCs are explored. Some of the fundamental mm-wave ADC building blocks such as track and hold ampli ers, data distribution networks and ip- ops are implemented in SiGe BiCMOS and CMOS technologies and characterized. Several record breaking circuits are presented along with systematic design methodology. The impact of these circuit blocks on the performance of the next generation ADCs is studied and experimentally veri ed using a 35-GS/s, 4-bit ADC-DAC chain implemented in a SiGe BiCMOS technology. Analog to Digital Converter mm-Wave Circuit Track and Hold Amplifier SiGe CMOS Data Converter TIALA Retimer 0544
63	High-speed analog-to-digital conversion in SiGe HBT technology Li, Xiangtao 19 May 2008 (has links) The objective of this research is to explore high-speed analog-to-digital converters (ADCs) using silicon-germanium (SiGe) heterojunction bipolar transistors (HBTs) for wireless digital receiver applications. The stringent requirements of ADCs for the high-performance next-generation wireless digital receiver include (1) low power, (2) low cost, (3) wide input signal bandwidth, (4) high sampling rate, and (5) medium to high resolution. The proposed research achieves the objective by implementing high-performance ADC's key building blocks and integrating these building blocks into a complete sigma-delta analog-to-digital modulator that satisfies the demanding specifications of next-generation wireless digital receiver applications. The scope of this research is divided into two main parts: (1) high-performance key building blocks of the ADC, and (2) high-speed sigma-delta analog-to-digital modulator. The research on ADC's building blocks includes the design of two high-speed track-and-hold amplifiers (THA) and two wide-bandwidth comparators operating at the sampling rate > 10 GS/sec with satisfying resolution. The research on high-speed sigma-delta analog-to-digital modulator includes the design and experimental characterization of a high-speed second-order low-pass sigma-delta modulator, which can operate with a sampling rate up to 20 GS/sec and with a medium resolution. The research is envisioned to demonstrate that the SiGe HBT technology is an ideal platform for the design of high-speed ADCs. ADC Analog-to-digital converter Track-and-hold amplifier Sigma-delta modulator Comparator SiGe Analog-to-digital converters Heterojunctions Bipolar transistors
64	Design & Implementation Of Low Power Sigma Delta ADCs For Wide Band Applications Harish, C 01 1900 (has links) (PDF) This thesis focuses on the design and implementation of low power Σ∆ ADCs in 130 nanometer CMOS technology. The design issues in the implementation of a third order ADC with a multi-bit and single bit quantizer are discussed. The advancement in CMOS technology has led to designing as much of electronics systems as possible with the digital circuits and digital signal processing replacing analog processing in most cases. Hence there is a need for digitizing analog signals with analog to digital converter (ADC). In communication systems this needs to be done immediately after the antenna in a receiver system. As this is difficult to implement due to high speed and high power consumption, RF signal is converted to a lower intermediate frequency (IF) and digitized. This work stresses low power implementation of high bandwidth Σ∆ ADCs for digitizing the IF. Design techniques involved in the implementation of a third order continuous time Σ∆ ADC with a 4 bit quantizer as well as a single bit quantizer for wide bandwidth are discussed. Moreover, a third order continuous time audio ADC implementation was also done. The behavioural modelling of the Σ∆ ADC along with clock jitter non-linearity model was developed and the issues in circuit design techniques are addressed. The continuous time ADCs’ major problem, namely, excess loop delay is discussed in detail and an efficient compensation technique for the same is implemented which allows a large reduction of power consumed by the ADC. Choice of loop filter architecture, quantizer and transistor level implementation are given that result in better immunity to offsets and process variations. Both the ADCs have been implemented using UMC 130 nm Mixed-mode RF-CMOS process and the simulation results for the multi-bit ADC gives a peak SNR of 56dB with a dynamic range of 65dB with power consumption of 2mW. The audio ADC achieves a peak SNR of 94.2dB with a dynamic range of 91dB. Analog to Digital Converter (ADC) CMOS Technologies Analog to Digital Signal Processing Sigma Delta ADC Wireless Applications Communication Engineering
65	Systém pro sběr dat s Raspberry Pi / System for data acquire with Raspberry Pi Ciprys, Michal January 2019 (has links) This work deals with the collection of data from analog sensors, their storage and display using the Raspberry Pi microcomputer. In more detail it deals with selecting the appropriate analog-to-digital converter, selecting the appropriate storage and database server, web server and application to display the measured data.
66	Lokalizace zvukového zdroje / Sound source localization Vélim, Jan January 2013 (has links) The paper discusses a possibility of localization of a sound source inside a wooden beam. The method is based on measuring signals from two microphones, assuming the sound source lies between the microphones. The position of the sound source is calculated from the delay between the signals. The calculation of the delay is done by correlation of the signals in the frequency range. ARM architecture microcontroller is used to for the calculations.
67	Řídicí jednotka indukčního ohřevu / Induction Heating Control Unit Válik, Martin January 2016 (has links) The text is focused on development induction heating coltroller. The motivation to create such a device was to correct deficiencies and add the necessary functionality for a device of this type. This was achieved mainly by adding the graphic display and USB interface. Graphic TFT display with buttons and a rotary encoder creates user interface. Part of the control unit is also circuit evaluateing temperature from three thermocouples. The paper dealt with the optimal solution for power supply, communication between control unit and power part, way of controlling graphical TFT display and selection of other components. The core is of course, suitable microcontroller, which manage all parts of the device.
68	Fully-Integrated CMOS pH, Electrical Conductivity, And Temperature Sensing System Asgari, Mohammadreza January 2018 (has links) No description available. Electrical Engineering
69	DESIGN OF ULTRA HIGH SPEED FLASH ADC, LOW POWER FOLDING AND INTERPOLATING ADC IN CMOS 90nm TECHNOLOGY Hiremath, Vinayashree 08 December 2010 (has links) No description available. Electrical Engineering Analog to digital converter Flash ADC Fat tree encoder Direct conversion encoder Folding ADC interpolation
70	A software radio approach to Global Navigation Satellite System receiver design Akos, Dennis M. January 1997 (has links) No description available. software radio approach Global Navigation Satellite System GNSS analog-to-digital converter

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