Analog and Mixed Signal Design towards a Miniaturized Sleep Apnea Monitoring Device

Sleep apnea is a sleep-induced breathing disorder with symptoms of momentary and often repetitive cessations in breathing rhythm or sustained reductions in breathing amplitude. The phenomenon is known to occur with varying degrees of severity in literally millions of people around the world and cause a range of chronicle health issues. In spite of its high prevalence and serious consequences, nearly 80% of people with sleep apnea condition remain undiagnosed. The current standard diagnosis technique, termed polysomnography or PSG, requires the patient to schedule and undergo a complex full-night sleep study in a specially-equipped sleep lab. Due to both high cost and substantial inconvenience, millions of apnea patients are still undiagnosed and thus untreated. This research work aims at a simple, reliable, and miniaturized solution for in-home sleep apnea diagnosis purposes. The proposed solution bears high-level integration and minimal interference with sleeping patients, allowing them to monitor their apnea conditions at the comfort of their homes. Based on a MEMS sensor and an effective apnea detection algorithm, a low-cost single-channel apnea screening solution is proposed. A custom designed IC chip implements the apnea detection algorithm using time-domain signal processing techniques. The chip performs autonomous apnea detection and scoring based on the patient’s airflow signals detected by the MEMS sensor. Variable sensitivity is enabled to accommodate different breathing signal amplitudes. The IC chip was fabricated in standard 0.5-μm CMOS technology. A prototype device was designed and assembled including a MEMS sensor, the apnea detection IC chip, a PSoC platform, and wireless transceiver for data transmission. The prototype device demonstrates a valuable screening solution with great potential to reach the broader public with undiagnosed apnea conditions. In a battery-operated miniaturized medical device, an energy-efficient analog-to-digital converter is an integral part linking the analog world of biomedical signals and the digital domain with powerful signal processing capabilities. This dissertation includes the detailed design of a successive approximation register (SAR) ADC for ultra-low power applications. The ADC adopts an asynchronous 2b/step scheme that halves both conversion time and DAC/digital circuit’s switching activities to reduce static and dynamic energy consumption. A low-power sleep mode is engaged at the end of all conversion steps during each clock period. The technical contributions of this ADC design include an innovative 2b/step reference scheme based on a hybrid R-2R/C-3C DAC, an interpolation-assisted time-domain 2b comparison scheme, and a TDC with dual-edge-comparison mechanism. The prototype ADC was fabricated in 0.18μm CMOS process with an active area of 0.103 mm^(2), and achieves an ENoB of 9.2 bits and an FoM of 6.7 fJ/conversion-step at 100-kS/s

Built-in self test of RF subsystems

textWith the rapid development of wireless and wireline communications, a variety of new standards and applications are emerging in the marketplace. In order to achieve higher levels of integration, RF circuits are frequently embedded into System on Chip (SoC) or System in Package (SiP) products. These developments, however, lead to new challenges in manufacturing test time and cost. Use of traditional RF test techniques requires expensive high frequency test instruments and long test time, which makes test one of the bottlenecks for reducing IC costs. This research is in the area of built-in self test technique for RF subsystems. In the test approach followed in this research, on-chip detectors are used to calculate circuits specifications, and data converters are used to collect the data for analysis by an on-chip processor. A novel on-chip amplitude detector has been designed and optimized for RF circuit specification test. By using on-chip detectors, both the system performance and specifications of the individual components can be accurately measured. On-chip measurement results need to be collected by Analog to Digital Converters (ADCs). A novel time domain, low power ADC has been designed for this purpose. The ADC architecture is based on a linear voltage controlled delay line. Using this structure results in a linear transfer function for the input dependent delay. The time delay difference is then compared to a reference to generate a digital code. Two prototype test chips were fabricated in commercial CMOS processes. One is for the RF transceiver front end with on-chip detectors; the other is for the test ADC. The 940MHz RF transceiver front-end was implemented with on-chip detectors in a 0.18 [micrometer] CMOS technology. The chips were mounted onto RF Printed Circuit Boards (PCBs), with tunable power supply and biasing knobs. The detector was characterized with measurements which show that the detector keeps linear performance over a wide input amplitude range of 500mV. Preliminary simulation and measurements show accurate transceiver performance prediction under process variations. A 300MS/s 6 bit ADC was designed using the novel time domain architecture in a 0.13 [micrometer] standard digital CMOS process. The simulation results show 36.6dB Signal to Noise Ratio (SNR), 34.1dB Signal to Noise and Distortion Ratio (SNDR) for 99MHz input, Differential Non-Linearity (DNL)<0.2 Least Significant Bit (LSB), and Integral Non-Linearity (INL)<0.5LSB. Overall chip power is 2.7mW with a 1.2V power supply. The built-in detector RF test was extended to a full transceiver RF front end test with a loop-back setup, so that measurements can be made to verify the benefits of the technique. The application of the approach to testing gain, linearity and noise figure was investigated. New detector types are also evaluated. In addition, the low-power delay-line based ADC was characterized and improved to facilitate gathering of data from the detector. Several improved ADC structures at the system level are also analyzed. The built-in detector based RF test technique enables the cost-efficient test for SoCs.Electrical and Computer Engineerin

Design of broadband inductor-less RF front-ends with high dynamic range for G.hn

System-on-Chip (SoC) was adopted in recent years as one of the solutions to reduce the cost of integrated systems. When the SoC solution started to be used, the final product was actually more expensive due to lower yield. The developments in integrated technology through the years allowed the integration of more components in lesser area with a better yield. Thus, SoCs became a widely used solution to reduced the cost of the final product, integrating into a single-chip the main parts of a system: analog, digital and memory. As integrated technology kept scaling down to allow a higher density of transistors and thus providing more functionality with the same die area, the analog RF parts of the SoC became a bottleneck to cost reduction as inductors occupy a large die area and do not scale down with technology. Hence, the trend moves toward the research and design of inductor-less SoCs that further reduce the cost of the final solution. Also, as the demand for home networking high-data-rates communication systems has increased over the last decade, several standards have been developed to satisfy the requirements of each application, the most popular being wireless local area networks (WLANs) based on the IEEE 802.11 standard. However, poor signal propagation across walls make WLANs unsuitable for high-speed applications such as high-definition in-home video streaming, leading to the development of wired technologies using the existing in-home infrastructure. The ITU-T G.hn recommendation (G.9960 and G.9961) unifies the most widely used wired infrastructures at home (coaxial cables, phone lines and power lines) into a single standard for high-speed data transmission of up to 1 Gb/s. The G.hn recommendation defines a unified networking over power lines, phone lines and coaxial cables with different plans for baseband and RF. The RF-coax bandplan, where this thesis is focused, uses 50 MHz and 100 MHz bandwidth channels with 256 and 512 carriers respectively. The center frequency can range from 350 MHz to 2450 MHz. The recommendation specifies a transmission power limit of 5 dBm for the 50 MHz bandplan and 8~dBm for the 100 MHz bandplan, therefore the maximum transmitted power in each carrier is the same for both bandplans. Due to the nature of an in-home wired environment, receivers that can handle both very large and very small amplitude signals are required; when transmitter and receiver are connected on the same electric outlet there is no channel attenuation and the signal-to-noise-plus-distortion ratio (SNDR) is dominated by the receiver linearity, whereas when transmitter and receiver are several rooms apart channel attenuation is high and the SNDR is dominated by the receiver noise figure. The high dynamic range specifications for these receivers require the use of configurable-gain topologies that can provide both high-linearity and low-noise for different configurations. Thus, this thesis has been aimed at researching high dynamic range broadband inductor-less topologies to be used as the RF front-end for a G.hn receiver complying with the provided specifications. A large part of the thesis has been focused on the design of the input amplifier of the front-end, which is the most critical stage as the noise figure and linearity of the input amplifier define the achievable overall specifications of the whole front-end. Three prototypes has been manufactured using a 65 nm CMOS process: two input RFPGAs and one front-end using the second RFPGA prototype.El "sistema en un chip" (SoC) fue adoptado recientemente como una de las soluciones para reducir el coste de sistemas integrados. Cuando se empezó a utilizar la solución SoC, el producto final era más caro debido al bajo rendimiento de producción. Los avances en tecnología integrada a lo largo de los años han permitido la integración de más componentes en menos área con mejoras en rendimiento. Por lo tanto, SoCs pasó a ser una solución ampliamente utilizada para reducir el coste del producto final, integrando en un único chip las principales partes de un sistema: analógica, digital y memoria. A medida que las tecnologías integradas se reducían en tamaño para permitir una mayor densisdad de transistores y proveer mayor funcionalidad con la misma área, las partes RF analógicas del SoC pasaron a ser la limitación en la reducción de costes ya que los inductores ocupan mucha área y no escalan con la tecnología. Por lo tanto, las tendencias en investigación se mueven hacia el diseño de SoCs sin inductores que todavía reducen más el coste final del producto. También, a medida que la demanda en sistemas de comunicación domésticos de alta velocidad ha crecido a lo largo de la última década, se han desarrollado varios estándares para satisfacer los requisitos de cada aplicación, siendo las redes sin hilos (WLANs) basadas en el estándar IEEE 802.11 las más populares. Sin embargo, una pobre propagación de señal a través de las paredes hacen que las WLANs sean inadecuadas para aplicaciones de alta-velocidad como transmisión de vídeo de alta definición en tiempo real, resultando en el desarrollo de tecnologías con hilos utilizando la infraestructura existente en los domicilios. La recomendación ITU-T G.hn (G.9960 and G.9961) unifica las principales infraestructuras con hilos domésticas (cables coaxiales, línias de teléfono y línias de electricidad) en un sólo estándar para la transmisión de datos hasta 1 Gb/s. La recomendación G.hn define una red unificada sobre línias de electricidad, de teléfono y coaxiales con diferentes esquemas para banda base y RF. El esquema RF-coax en el cual se basa esta tesis, usa canales con un ancho de banda de 50 MHz y 100 MHz con 256 y 512 portadoras respectivamente. La frecuencia centra puede variar desde 350 MHz hasta 2450 MHz. La recomendación especifica un límite en la potencia de transmisión de 5 dBm para el esquema de 50 MHz y 8 dBm para el esquema de 100 MHz, de tal forma que la potencia máxima por portadora es la misma en ambos esquemas. Debido a la estructura de un entorno doméstico con hilos, los receptores deben ser capaces de procesar señales con amplitud muy grande o muy pequeña; cuando transmisor y receptor están conectados en la misma toma eléctrica no hay atenuación de canal y el ratio de señal a rudio más distorsión (SNDR) está dominado por la linealidad del receptor, mientras que cuando transmisor y receptor están separados por varias habitaciones la atenuación es elevada y el SNDR está dominado por la figura de ruido del receptor. Los elevados requisitos de rango dinámico para este tipo de receptores requieren el uso de topologías de ganancia configurable que pueden proporcionar tanto alta linealidad como bajo ruido para diferentes configuraciones. Por lo tanto, esta tesis está encarada a la investigación de topologías sin inductores de banda ancha y elevado rango dinámico para ser usadas a la entrada de un receptor G.hn cumpliendo con las especificaciones proporcionadas. Una gran parte de la tesis se ha centrado en el diseño del amplificador de entrada al ser la etapa más crítica, ya que la figura de ruido y linealidad del amplificador de entrada definen lás máximas especificaciones que el sistema puede conseguir. Se han fabricado 3 prototipos con un proceso CMOS de 65 nm: 2 amplificadores y un sistema completo con amplificador y mezclador.Postprint (published version

Extreme Temperature Switch Mode Power Supply Based on Vee-square Control Using Silicon Carbide, Silicon on Sapphire, Hybrid Technology

Switch mode power supplies, commonly known as SMPS are basic building blocks of the electronic systems. SMPS performs power regulation by accepting a raw input voltage and transforming it to required voltage at output with desired characteristics. Electronic systems used in applications such as deep well oil drilling, geothermal wells and deep space explorations is expected to operate under extremely harsh conditions like elevated temperature, high pressure and radiation prone environments. To support the onboard electronics in these applications, SMPS capable of operating at extreme temperatures are of high interest.This research work deals with the design and development of a switch mode power supply capable of operating over the temperature range of 300 degree centigrade (�C). Silicon carbide field effect transistors are used as power devices in the design to tolerate these extreme high ambient temperatures without compromising power handling capability. The simplest yet robust vee square control architecture is adopted for control mechanism. The control electronics are implemented as an integrated circuit in 0.5 �m silicon on sapphire process. The supporting components like high temperature tolerant inductors and capacitors are identified by evaluating various samples at elevated temperature. This is the first demonstration of SMPS capable of operating at 275�C as a standalone component. Also for the first time, a gate drive mechanism based on planar transformer architecture is studied and presented for high temperature operation. A low cost packaging technique suited for harsh environment operation is proposed based on gold on aluminum nitride thin film technology. The basic analog building blocks of the system, such as comparator, voltage reference and rail-to-rail amplifiers are made available in discrete packages for use at temperatures above 275�C. A SMPS prototype on a 1.8 square inches substrate is developed and tested. Test results indicate that the system is capable of operating continuously at 275�C for extended period of time, providing the desired performance characteristics.School of Electrical & Computer Engineerin

Sincronização em sistemas integrados a alta velocidade

Doutoramento em Engenharia ElectrotécnicaA distribui ção de um sinal relógio, com elevada precisão espacial (baixo skew) e temporal (baixo jitter ), em sistemas sí ncronos de alta velocidade tem-se revelado uma tarefa cada vez mais demorada e complexa devido ao escalonamento da tecnologia. Com a diminuição das dimensões dos dispositivos e a integração crescente de mais funcionalidades nos Circuitos Integrados (CIs), a precisão associada as transições do sinal de relógio tem sido cada vez mais afectada por varia ções de processo, tensão e temperatura. Esta tese aborda o problema da incerteza de rel ogio em CIs de alta velocidade, com o objetivo de determinar os limites do paradigma de desenho sí ncrono. Na prossecu ção deste objectivo principal, esta tese propõe quatro novos modelos de incerteza com âmbitos de aplicação diferentes. O primeiro modelo permite estimar a incerteza introduzida por um inversor est atico CMOS, com base em parâmetros simples e su cientemente gen éricos para que possa ser usado na previsão das limitações temporais de circuitos mais complexos, mesmo na fase inicial do projeto. O segundo modelo, permite estimar a incerteza em repetidores com liga ções RC e assim otimizar o dimensionamento da rede de distribui ção de relógio, com baixo esfor ço computacional. O terceiro modelo permite estimar a acumula ção de incerteza em cascatas de repetidores. Uma vez que este modelo tem em considera ção a correla ção entre fontes de ruí do, e especialmente util para promover t ecnicas de distribui ção de rel ogio e de alimentação que possam minimizar a acumulação de incerteza. O quarto modelo permite estimar a incerteza temporal em sistemas com m ultiplos dom ínios de sincronismo. Este modelo pode ser facilmente incorporado numa ferramenta autom atica para determinar a melhor topologia para uma determinada aplicação ou para avaliar a tolerância do sistema ao ru ído de alimentação. Finalmente, usando os modelos propostos, são discutidas as tendências da precisão de rel ogio. Conclui-se que os limites da precisão do rel ogio são, em ultima an alise, impostos por fontes de varia ção dinâmica que se preveem crescentes na actual l ogica de escalonamento dos dispositivos. Assim sendo, esta tese defende a procura de solu ções em outros ní veis de abstração, que não apenas o ní vel f sico, que possam contribuir para o aumento de desempenho dos CIs e que tenham um menor impacto nos pressupostos do paradigma de desenho sí ncrono.Distributing a the clock simultaneously everywhere (low skew) and periodically everywhere (low jitter) in high-performance Integrated Circuits (ICs) has become an increasingly di cult and time-consuming task, due to technology scaling. As transistor dimensions shrink and more functionality is packed into an IC, clock precision becomes increasingly a ected by Process, Voltage and Temperature (PVT) variations. This thesis addresses the problem of clock uncertainty in high-performance ICs, in order to determine the limits of the synchronous design paradigm. In pursuit of this main goal, this thesis proposes four new uncertainty models, with di erent underlying principles and scopes. The rst model targets uncertainty in static CMOS inverters. The main advantage of this model is that it depends only on parameters that can easily be obtained. Thus, it can provide information on upcoming constraints very early in the design stage. The second model addresses uncertainty in repeaters with RC interconnects, allowing the designer to optimise the repeater's size and spacing, for a given uncertainty budget, with low computational e ort. The third model, can be used to predict jitter accumulation in cascaded repeaters, like clock trees or delay lines. Because it takes into consideration correlations among variability sources, it can also be useful to promote oorplan-based power and clock distribution design in order to minimise jitter accumulation. A fourth model is proposed to analyse uncertainty in systems with multiple synchronous domains. It can be easily incorporated in an automatic tool to determine the best topology for a given application or to evaluate the system's tolerance to power-supply noise. Finally, using the proposed models, this thesis discusses clock precision trends. Results show that limits in clock precision are ultimately imposed by dynamic uncertainty, which is expected to continue increasing with technology scaling. Therefore, it advocates the search for solutions at other abstraction levels, and not only at the physical level, that may increase system performance with a smaller impact on the assumptions behind the synchronous design paradigm