Design of a Spiral-Mode Microstrip Antenna and Matching Circuitry for Ultra-Wide-Band Receivers

Abstract

Design of sigma-delta modulators for analog-to-digital conversion intensively using passive circuits

This thesis presents the analysis, design implementation and experimental evaluation of passiveactive discrete-time and continuous-time Sigma-Delta (ΣΔ) modulators (ΣΔMs) analog-todigital converters (ADCs). Two prototype circuits were manufactured. The first one, a discrete-time 2nd-order ΣΔM, was designed in a 130 nm CMOS technology. This prototype confirmed the validity of the ultra incomplete settling (UIS) concept used for implementing the passive integrators. This circuit, clocked at 100 MHz and consuming 298 μW, achieves DR/SNR/SNDR of 78.2/73.9/72.8 dB, respectively, for a signal bandwidth of 300 kHz. This results in a Walden FoMW of 139.3 fJ/conv.-step and Schreier FoMS of 168 dB. The final prototype circuit is a highly area and power efficient ΣΔM using a combination of a cascaded topology, a continuous-time RC loop filter and switched-capacitor feedback paths. The modulator requires only two low gain stages that are based on differential pairs. A systematic design methodology based on genetic algorithm, was used, which allowed decreasing the circuit’s sensitivity to the circuit components’ variations. This continuous-time, 2-1 MASH ΣΔM has been designed in a 65 nm CMOS technology and it occupies an area of just 0.027 mm2. Measurement results show that this modulator achieves a peak SNR/SNDR of 76/72.2 dB and DR of 77dB for an input signal bandwidth of 10 MHz, while dissipating 1.57 mW from a 1 V power supply voltage. The ΣΔM achieves a Walden FoMW of 23.6 fJ/level and a Schreier FoMS of 175 dB. The innovations proposed in this circuit result, both, in the reduction of the power consumption and of the chip size. To the best of the author’s knowledge the circuit achieves the lowest Walden FOMW for ΣΔMs operating at signal bandwidth from 5 MHz to 50 MHz reported to date

Time-domain optimization of amplifiers based on distributed genetic algorithms

Thesis presented in partial fulfillment of the requirements for the degree of Doctor of Philosophy in the subject of Electrical and Computer EngineeringThe work presented in this thesis addresses the task of circuit optimization, helping the designer facing the high performance and high efficiency circuits demands of the market and technology evolution. A novel framework is introduced, based on time-domain analysis, genetic algorithm optimization, and distributed processing. The time-domain optimization methodology is based on the step response of the amplifier. The main advantage of this new time-domain methodology is that, when a given settling-error is reached within the desired settling-time, it is automatically guaranteed that the amplifier has enough open-loop gain, AOL, output-swing (OS), slew-rate (SR), closed loop bandwidth and closed loop stability. Thus, this simplification of the circuit‟s evaluation helps the optimization process to converge faster. The method used to calculate the step response expression of the circuit is based on the inverse Laplace transform applied to the transfer function, symbolically, multiplied by 1/s (which represents the unity input step). Furthermore, may be applied to transfer functions of circuits with unlimited number of zeros/poles, without approximation in order to keep accuracy. Thus, complex circuit, with several design/optimization degrees of freedom can also be considered. The expression of the step response, from the proposed methodology, is based on the DC bias operating point of the devices of the circuit. For this, complex and accurate device models (e.g. BSIM3v3) are integrated. During the optimization process, the time-domain evaluation of the amplifier is used by the genetic algorithm, in the classification of the genetic individuals. The time-domain evaluator is integrated into the developed optimization platform, as independent library, coded using C programming language. The genetic algorithms have demonstrated to be a good approach for optimization since they are flexible and independent from the optimization-objective. Different levels of abstraction can be optimized either system level or circuit level. Optimization of any new block is basically carried-out by simply providing additional configuration files, e.g. chromosome format, in text format; and the circuit library where the fitness value of each individual of the genetic algorithm is computed. Distributed processing is also employed to address the increasing processing time demanded by the complex circuit analysis, and the accurate models of the circuit devices. The communication by remote processing nodes is based on Message Passing interface (MPI). It is demonstrated that the distributed processing reduced the optimization run-time by more than one order of magnitude. Platform assessment is carried by several examples of two-stage amplifiers, which have been optimized and successfully used, embedded, in larger systems, such as data converters. A dedicated example of an inverter-based self-biased two-stage amplifier has been designed, laid-out and fabricated as a stand-alone circuit and experimentally evaluated. The measured results are a direct demonstration of the effectiveness of the proposed time-domain optimization methodology.Portuguese Foundation for the Science and Technology (FCT

Sistema de optimização de amplificadores em ambiente distribuído

Tese de Mestrado em Engenharia Electrotécnica e de ComputadoresEste trabalho apresenta um ambiente distribuído de optimização de circuitos amplificadores baseado na metodologia “Message Passing Interface” (MPI). O software desenvolvido integra dois componentes: algoritmos genéticos e código de um simulador "open-source", NGSPICE. O trabalho utiliza uma arquitectura cliente-servidor para o processamento de simulações em paralelo / distribuído. Desta forma o desempenho do optimizador aumenta e consegue-se reduzir substancialmente o tempo de optimização dos circuitos. Utilizou-se modelos de simulação BSIM3v3 que garantem resultados mais precisos. Este novo método de optimização possibilita ainda (re)aproveitamento de computadores, e.g. computadores pessoais ou máquinas profissionais topo de gama. A capacidade de processamento total pode ser tanto maior quanto maior o número de máquinas disponíveis e suas capacidades de processamento

Fast and Robust Design of CMOS VCO for Optimal Performance

The exponentially growing design complexity with technological advancement calls for a large scope in the analog and mixed signal integrated circuit design automation. In the automation process, performance optimization under different environmental constraints is of prime importance. The analog integrated circuits design strongly requires addressing multiple competing performance objectives for optimization with ability to find global solutions in a constrained environment. The integrated circuit (IC) performances are significantly affected by the device, interconnect and package parasitics. Inclusion of circuit parasitics in the design phase along with performance optimization has become a bare necessity for faster prototyping. Besides this, the fabrication process variations have a predominant effect on the circuit performance, which is directly linked to the acceptability of manufactured integrated circuit chips. This necessitates a manufacturing process tolerant design. The development of analog IC design methods exploiting the computational intelligence of evolutionary techniques for optimization, integrating the circuit parasitic in the design optimization process in a more meaningful way and developing process fluctuation tolerant optimal design is the central theme of this thesis. Evolutionary computing multi-objective optimization techniques such as Non-dominated Sorting Genetic Algorithm-II and Infeasibility Driven Evolutionary Algorithm are used in this thesis for the development of parasitic aware design techniques for analog ICs. The realistic physical and process constraints are integrated in the proposed design technique. A fast design methodology based on one of the efficient optimization technique is developed and an extensive worst case process variation analysis is performed. This work also presents a novel process corner variation aware analog IC design methodology, which would effectively increase the yield of chips in the acceptable performance window. The performance of all the presented techniques is demonstrated through the application to CMOS ring oscillators, current starved and xi differential voltage controlled oscillators, designed in Cadence Virtuoso Analog Design Environment