Fast opamp-free delta sigma modulator

Thomas, Daniel E.

23 August 2001

Switched-capacitor (SC) circuits are commonly used for analog signal processing because they can be used to realize precision filters and data converters on an integrated circuit (IC). However, for high speed applications SC circuit operating speeds are limited by the internally-compensated opamps found in SC integrators, a common building block of these circuits. This thesis studies gain stages that eliminate the internal compensation, thus allowing the SC circuits to operate at significantly higher operating speeds. An inverter-based SC integrator is presented. The proposed SC integrator is built with a pseudo-differential structure to improve its rejection of common-mode noise, such as charge injection and clock feedthrough. The proposed integrator also incorporates correlated double sampling (CDS) to boost its effective DC gain. Clock-boosting and switch bootstrapping techniques are not used in the proposed circuit, even though it uses a low supply voltage. To verify the speed advantage of the proposed circuit, a high speed delta sigma (Δ∑) modulator was designed in a 1.8V, 0.18μm CMOS technology. The designed Δ∑ modulator operates at a clock frequency of 500MHz. Circuit implementation and layout floorplan are described. The design is based on MATLAB and SpectreS simulations. / Graduation date: 2002

The design of delta-sigma modulators for multi-standard RF receivers

Liu, Mingliang

09 June 2003

The transition from second-generation (2G) to third-generation (3G) wireless cellular and cordless telephone systems requires multi-standard adaptability in a single RF receiver equipment. An important answer to this request is the use of Delta-Sigma modulators for IF-to-baseband conversion, which will satisfy the dynamic range requirements for digital signal processing, and at the same time, add adaptability and programmability to the characteristics of a RF receiver. This thesis addresses the issues of designing a Delta-Sigma modulator for a multi-standard wireless receiver. A single-loop third-order modulator topology suitable for low power and high integration multi-standard receiver design is proposed. The trade-offs in the modulator design are also presented and explained. The modulator, which has been implemented as a part of a monolithic receiver chip, will be fabricated in a standard 0.35-��m CMOS process. The post-layout simulation results have verified the outcomes of system analysis. / Graduation date: 2004

Analysis and design of CMOS RF LNAs with ESD protection

Chandrasekhar, Vinay

01 April 2002

An analysis that accounts for the effect of standard electrostatic discharge (ESD) structures on critical LNA specifications of noise figure, input matching and gain is presented. It is shown that the ESD structures degrade LNA performance particularly for higher frequency applications. Two LNAs, one with ESD protection and one without, which operate at 2.4 GHz have been fabricated in a 0.l5��m CMOS process. The LNAs feature one of the best reported performances for CMOS LNAs to date. The LNA with ESD protection achieves a gain of 12dB, a NF of 2.77dB and an IIP3 of 2.4dBm with a power consumption of 4.65mW. The LNA without ESD protection achieves a gain of 14dB, a NF of 2.36dB and an 11P3 of -2.2dBm with a power consumption of 4.65mW. / Graduation date: 2002

Amplifiers (Electronics) -- Design

Design of high-speed adaptive parallel multi-level decision feedback equalizer

Xiang, Yihai

26 February 1997

Multi-level decision feedback equalization (MDFE) is an effective technique to remove inter-symbol interference (ISI) from disk readback signals, which uses the simple architecture of decision feedback equalization. Parallelism which doubles the symbol rate can be realized by setting the first tap of the feedback filter to zero. A mixed-signal implementation has been chosen for the parallel MDFE, in which coefficients for the 9-tap feedback filter are adapted in the digital domain by 10-bit up/ down counters; 6-bit current mode D/A converters are used to convert digital coefficients to differential current signals which are summed with the forward equalizer (FE) output, and a flash A/D is used to make decisions and generate error signals for adaptation. In this thesis, a description of the parallel structure and the adaptation algorithm are presented with behavioral level verification. The circuit design and layout were carried out in HP 1.2um n-well CMOS process. The design of the high-speed counter and the current-mode D/A are discussed. HSPICE simulations show that a symbol rate of 100Mb/s for the feedback equalizer is readily achieved. / Graduation date: 1997

Design of high-speed low-power analog CMOS decision feedback equalizers

Su, Wenjun

08 July 1996

Decision feedback equalizer (DFE) is an effective method to remove inter-symbol interference (ISI) from a disk-drive read channel. Analog IC implementations of DFE potentially offers higher speed, smaller die area, and lower power consumption when compared to their digital counterparts. Most of the available DFE equalizers were realized by using digital FIR filters preceded by a flash A/D converter. Both the FIR filter and flash A/D converter are the major contributers to the power dissipation. However, this project focuses on the analog IC implementations of the DFE to achieve high speed and low power consumption. In other words, this project gets intensively involved in the design of a large-input highly-linear voltage-to-current converter, the design of a high-speed low-power 6-bit comparator, and the design of a high-speed low-power 6-bit current-steering D/A converter. The design and layout for the proposed analog equalizer are carried out in a 1.2 pm n-well CMOS process. HSPICE simulations show that an analog DFE with 100 MHz clock frequency and 6-bit accuracy can be easily achieved. The power consumption for all the analog circuits is only about 24mW operating under a single 5V power supply. / Graduation date: 1997

System oriented delta sigma analog-to-digital modulator design for ultra high precisoin data acquisition applications

Yang, Yuqing, Ph. D.

05 October 2012

As high precision data acquisition systems continue to improve their performance and power efficiency to migrate into portable devices, increasing demands are placed on the performance and power efficiency of the analog-to-digital conversion modulator. On the other hand, analog-to-digital modulator performance is largely limited by several major noise sources including thermal noise, flicker noise, quantization noise leakage and internal analog and digital coupling noise. Large power consumption and die area are normally required to suppress the above noise energies, which are the major challenges to achieve power efficiency and cost targets for modern day high precision converter design. The main goal of this work is to study various approaches and then propose and validate the most suitable topology to achieve the desired performance and power efficiency specifications, up to 100 kHz bandwidth with 16-21 bits of resolution. This work will first study various analog-to-digital conversion architectures ranging from Nyquist converters such as flash, pipeline, to the delta sigma architecture. Advantages and limitations of each approach will be compared to develop the criteria for the optimal modulator architecture. Second, this work will study analog sub-circuit blocks such as opamp, comparator and reference voltage generator, to compare the advantages and limitations of various design approaches to develop the criteria for the optimal analog sub circuit design. Third, this work will study noise contributions from various sources such as thermal noise, flicker noise and coupling noise, to explore alternative power and die area efficient approaches to suppress the noise. Finally, a new topology will be proposed to meet all above criteria and adopt the new noise suppression concepts, and will be demonstrated to be the optimal approach. The main difference between this work from previous ones is that current work places emphasis on the integration of the modulator architecture design and analog sub-circuit block research efforts. A high performance stereo analog-to-digital modulator is designed based on the new approach and manufactured in silicon. The chip is measured in the lab and the measurement results reported in the dissertation. / text

A wideband CMOS low-noise amplifier for UHF applications

Lo, Ivy Iun

January 2005

Thesis (M.S.)--University of Hawaii at Manoa, 2005. / Includes bibliographical references (leaves 95-98). / xii, 98 leaves, bound ill. 29 cm

Návrh metodiky řešení elektronického zabezpečeni objektu / Proposal of methodology for solving burglar alarm system for buildings

Malý, Luděk

January 2008

Master’s Thesis is consider to security system design. In this Theses is described methodology of proposal of electronic security alarm according to valid standards and rules. In terms of standard and specification is created way of computerization of this design. Consequently, this procedure is software implemented. Results of algorithmic design are reviewed on hypothetic object.

Teaching Creative Digital Hardware Design

Zainee, N.B.M., Noras, James M.

January 2013

yes / Engineering undergraduates not only need to learn facts, but also how to be creative in the open-ended situations they will encounter in their professional careers. Our final year Honours module gives students a grounding in digital systems design, mainly using VLSI for design entry and simulation. The second half of our module is a design exercise, which has straightforward aspects, but which allows motivated students to undertake progressively open-ended investigations. Our educational framework is guided by recommendations of professional bodies promoting excellence and encouragement of creativity in engineering development. (C) 2013 The Authors. Published by Elsevier Ltd.

Fabrication of infrared antennas

Gritz, Michael A.

01 April 2003

No description available.

Electrical and Computer Engineering

Engineering

Systems and Communications