Clock multiplication techniques for high-speed I/Os

Generation of a low-jitter, high-frequency clock from a low-frequency reference clock using classical analog phase-locked loops (PLLs) requires a large loop filter capacitor and power hungry oscillator. Digital PLLs can help reduce area but their jitter performance is severely degraded by quantization error. In this dissertation different clock multiplication techniques have been explored that can be suitable for high-speed wireline systems. With the emphasis on ring oscillator based architecture using cascaded stages, three possible architectures are explored. First, a scrambling TDC (STDC) is presented to improve deterministic jitter (DJ) performance when used with a low-frequency reference clock. A cascaded architecture with digital multiplying delay locked loop as the first stage and hybrid analog/digital PLL as the second stage is used to achieve low random jitter in a power efficient manner. Fabricated in a 90nm CMOS process, the prototype frequency synthesizer consumes 4.76mW power from a 1.0V supply and generates 160MHz and 2.56 GHz output clocks from a 1.25MHz crystal reference frequency. The long-term absolute jitter of the 60MHz digital MDLL and 2.56 GHz digital PLL outputs are 2.4 psrms and 4.18 psrms, while the peak-to-peak jitter is 22.1 ps and 35.2 ps, respectively. The proposed frequency synthesizer occupies an active die area of 0.16mm2 and achieves power efficiency of 1.86 mW/GHz. Second, a hybrid phase/current-mode phase interpolator (HPC-PI) is presented to improve phase noise performance of ring oscillator-based fractional-N PLLs. The proposed HPC-PI alleviates the bandwidth trade-off between VCO phase noise suppression and ΔΣ quantization noise suppression. By combining the phase detection and interpolation functions into an XOR phase detector/interpolator (XOR PD-PI) block, accurate quantization error cancellation is achieved without using calibration. Use of a digital MDLL in front of the fractional-N PLL helps in alleviating the bandwidth limitation due to reference frequency and enables bandwidth extension even further. The extended bandwidth helps in suppressing the ring-VCO phase noise and lowering the in-band noise floor. Fabricated in 65nm CMOS process, the prototype generates fractional frequencies from 4.25 to 4.75 GHz, with an in-band phase noise floor of -104 dBc/Hz and 1.5 psrms integrated jitter. The clock multiplier achieves power efficiency of 2.4mW/GHz and FoM of -225.8 dB. Finally, an efficient clock generation, recovery, and distribution techniques for flexible-rate transceivers are presented. Using a fixed-frequency low-jitter clock provided by an integer-N PLL, fractional frequencies are generated/recovered locally using multi-phase fractional clock multipliers. Fabricated in a 65nm CMOS, the prototype transceiver can be programmed to operate at any rate from 3-to-10 Gb/s. At 10 Gb/s, integrated jitter of the Tx output and recovered clock is 360 fsrms and 758 fsrms, respectively

Methods and Devices for Modifying Active Paths in a K-Delta-1-Sigma Modulator

The invention relates to an improved K-Delta-1-Sigma Modulators (KG1Ss) that achieve multi GHz sampling rates with 90 nm and 45 nm CMOS processes, and that provide the capability to balance performance with power in many applications. The improved KD1Ss activate all paths when high performance is needed (e.g. high bandwidth), and reduce the effective bandwidth by shutting down multiple paths when low performance is required. The improved KD1Ss can adjust the baseband filtering for lower bandwidth, and can provide large savings in power consumption while maintaining the communication link, which is a great advantage in space communications. The improved KD1Ss herein provides a receiver that adjusts to accommodate a higher rate when a packet is received at a low bandwidth, and at a initial lower rate, power is saved by turning off paths in the KD1S Analog to Digital Converter, and where when a higher rate is required, multiple paths are enabled in the KD1S to accommodate the higher band widths

Fractional-N DLL for clock synchronization

Master'sMASTER OF ENGINEERIN

Design and realization of fully integrated multiband and multistandard bi-cmos sigma delta frequency synthesizer

Wireless communication has grown, exponentially, with wide range of applications offered for the customers. Among these, WLAN (2.4-2.5GHz, 3.6-3.7GHzand 4.915- 5.825GHz GHz), Bluetooth (2.4 GHz), and WiMAX (2.500-2.696 GHz, 3.4-3.8 GHz and 5.725-5.850 GHz) communication standard/technologies have found largest use local area, indoor – outdoor communication and entertainment system applications. One of the recent trends in this area of technology is to utilize compatible standards on a single chip solutions, while meeting the requirements of each, to provide customers systems with smaller size, lower power consumption and cheaper in cost. In this thesis, RF – Analog, and – Digital Integrated Circuit design methodologies and techniques are applied to realize a multiband / standart (WLAN and WiMAX) operation capable Voltage- Controlled-Oscillator (VCO) and Frequency Synthesizer. Two of the major building blocks of wireless communication systems are designed using 0.35 μm, AMS-Bipolar (HBT)-CMOS process technology. A new inductor switching concept is implemented for providing the multiband operation capability. Performance parameters such as operating frequencies, phase noise, power consumption, and tuning range are modeled and simulated using analytical approaches, ADS® and Cadence® design and simulation environments. Measurement and/or Figure-of-Merit (FOM) values of our circuits have revealed results that are comparable with already published data, using the similar technology, in the literature, indicating the strength of the design methodologies implemented in this study

CMOS dual-modulus prescaler design for RF frequency synthesizer applications.

Ng Chong Chon.Thesis (M.Phil.)--Chinese University of Hong Kong, 2005.Includes bibliographical references (leaves 100-103).Abstract in English and Chinese.摘要 --- p.iiiAcknowledgments --- p.ivContents --- p.viList of Figures --- p.ixList of Tables --- p.xiiChapter Chapter 1 --- Introduction --- p.1Chapter 1.1 --- Motivation --- p.1Chapter 1.2 --- Thesis Organization --- p.4Chapter Chapter 2 --- DMP Architecture --- p.6Chapter 2.1 --- Conventional DMP --- p.6Chapter 2.1.1 --- Operating Principle --- p.7Chapter 2.1.2 --- Disadvantages --- p.10Chapter 2.2 --- Pre-processing Clock Architecture --- p.10Chapter 2.2.1 --- Operating Principle --- p.11Chapter 2.2.2 --- Advantages and Disadvantages --- p.12Chapter 2.3 --- Phase-switching Architecture --- p.13Chapter 2.3.1 --- Operating Principle --- p.13Chapter 2.3.2 --- Advantages and Disadvantages --- p.14Chapter 2.4 --- Summary --- p.15Chapter Chapter 3 --- Full-Speed Divider Design --- p.16Chapter 3.1 --- Introduction --- p.16Chapter 3.2 --- Working Principle --- p.16Chapter 3.3 --- Design Issues --- p.18Chapter 3.4 --- Device Sizing --- p.19Chapter 3.5 --- Layout Considerations --- p.20Chapter 3.6 --- Input Sensitivity --- p.22Chapter 3.7 --- Modeling --- p.24Chapter 3.8 --- Review on Different Divider Designs --- p.28Chapter 3.8.1 --- Divider with Dynamic-Loading Technique --- p.28Chapter 3.8.2 --- Divider with Negative-Slew Technique --- p.30Chapter 3.8.3 --- LC Injection-Locked Frequency Divider --- p.32Chapter 3.8.4 --- Dynamic True Single Phase Clock Frequency Divider --- p.34Chapter 3.9 --- Summary --- p.42Chapter Chapter 4 --- 3V 900MHz Low Noise DMP --- p.43Chapter 4.1 --- Introduction --- p.43Chapter 4.2 --- Proposed DMP Topology --- p.46Chapter 4.3 --- Circuit Design and Implementation --- p.49Chapter 4.4 --- Simulation Results --- p.51Chapter 4.5 --- Summary --- p.53Chapter Chapter 5 --- 1.5V 2.4GHz Low Power DMP --- p.54Chapter 5.1 --- Introduction --- p.54Chapter 5.2 --- Proposed DMP Topology --- p.56Chapter 5.3 --- Circuit Design and Implementation --- p.59Chapter 5.3.1 --- Divide-by-4 stage --- p.59Chapter 5.3.2 --- TSPC dividers --- p.63Chapter 5.3.3 --- Phase-selection Network --- p.63Chapter 5.3.4 --- Mode-control Logic --- p.64Chapter 5.3.5 --- Duty-cycle Transformer --- p.65Chapter 5.3.6 --- Glitch Problem --- p.66Chapter 5.3.7 --- Phase-mismatch Problem --- p.70Chapter 5.4 --- Simulation Results --- p.70Chapter 5.5 --- Summary --- p.74Chapter Chapter 6 --- 1.5V 2.4GHz Wideband DMP --- p.75Chapter 6.1 --- Introduction --- p.75Chapter 6.2 --- Proposed DMP Architecture --- p.75Chapter 6.3 --- Divide-by-4 Stage --- p.76Chapter 6.3.1 --- Current-switch Combining --- p.76Chapter 6.3.2 --- Capacitive Load Reduction --- p.77Chapter 6.4 --- Simulation Results --- p.81Chapter 6.5 --- Summary --- p.83Chapter Chapter 7 --- Experimental Results --- p.84Chapter 7.1 --- Introduction --- p.84Chapter 7.2 --- Equipment Setup --- p.84Chapter 7.3 --- Measurement Results --- p.85Chapter 7.3.1 --- 3V 900GHz Low Noise DMP --- p.85Chapter 7.3.2 --- 1.5V 2.4GHz Low Power DMP --- p.88Chapter 7.3.3 --- 1.5V 2.4GHz Wideband DMP --- p.93Chapter 7.3 --- Summary --- p.96Chapter Chapter 8 --- Conclusions and Future Works --- p.98Chapter 8.1 --- Conclusions --- p.98Chapter 8.2 --- Future Works --- p.99References --- p.100Publications --- p.10

Cryogenic Control Beyond 100 Qubits

Quantum computation has been a major focus of research in the past two decades, with recent experiments demonstrating basic algorithms on small numbers of qubits. A large-scale universal quantum computer would have a profound impact on science and technology, providing a solution to several problems intractable for classical computers. To realise such a machine, today's small experiments must be scaled up, and a system must be built which provides control and measurement of many hundreds of qubits. A device of this scale is challenging: qubits are highly sensitive to their environment, and sophisticated isolation techniques are required to preserve the qubits' fragile states. Solid-state qubits require deep-cryogenic cooling to suppress thermal excitations. Yet current state-of-the-art experiments use room-temperature electronics which are electrically connected to the qubits. This thesis investigates various scalable technologies and techniques which can be used to control quantum systems. With the requirements for semiconductor spin-qubits in mind, several custom electronic systems, to provide quantum control from deep cryogenic temperatures, are designed and measured. A system architecture is proposed for quantum control, providing a scalable approach to executing quantum algorithms on a large number of qubits. Control of a gallium arsenide qubit is demonstrated using a cryogenically operated FPGA driving custom gallium arsenide switches. The cryogenic performance of a commercial FPGA is measured, as the main logic processor in a cryogenic quantum control system, and digital-to-analog converters are analysed during cryogenic operation. Recent work towards a 100-qubit cryogenic control system is shown, including the design of interconnect solutions and multiplexing circuitry. With qubit fidelity over the fault-tolerant threshold for certain error correcting codes, accompanying control platforms will play a key role in the development of a scalable quantum machine

Subsampling receivers with applications to software defined radio systems

Este trabajo de tesis propone la utilización sistemas basados en submuestreo como una alternativa para la implementación de la etapa de down-conversion de los receptores de radio frecuencia (RF) empleados para aplicaciones multi-estándar y SDR (Software Defined Radio). El objetivo principal será el de optimizar el diseño en cuanto a flexibilidad y simplicidad, las cuales son propiedades inherentes en los sistemas basados en submuestreo. Por tanto, como reducir el número de componentes al mínimo es clave cuando un mismo receptor procesa diferentes estándares de comunicación, las arquitecturas basadas en submuestreo han sido seleccionadas, donde la reusabilidad de los componentes empleados es posible, así como la reducción de los costes totales de los receptores de comunicación y de los equipos de certificación que emplean estas arquitecturas. Un motivo adicional por el que los sistemas basados en submuestreo han sido seleccionados es el concerniente a la topología del receptor. Como la idea de la tecnología SDR es implementar todas las funcionalidades del receptor (filtrado, amplificación) en el dominio digital, el convertidores analógico-digital (ADC) deberá estar localizado en la cadena de recepción lo más cerca posible a la antena, siendo el objetivo final el convertir la señal directamente de RF a digital. Sin embargo, con los actuales ADC no es posible implementar esta idea debido al alto ancho de banda que necesitarían sin perder resolución para cubrir las especificaciones de los estándares de comunicaciones inalámbricas. Por tanto, los sistemas basados en submuestreo se presentan como la opción más adecuada para implementar este tipo de sistemas debido a que pueden muestrear la señal de entrada por debajo de la tasa de Nyquist, si se cumplen ciertas restricciones en cuanto a la elección de la frecuencia de muestreo. De este modo, los requerimientos del ADC serán relajados ya que, usando estas arquitecturas, este componente procesará la señal a frecuencias intermedias. Una vez se han introducido los conceptos principales de las técnicas de submuestreo, esta tesis doctoral presenta el diseño de una tarjeta de adquisición de datos basada en submuestreo con la finalidad de ser implementada como un receptor de test y certificación de banda ancha. El sistema propuesto proporciona una alta resolución para un elevado ancho de banda, a partir del uso de un S&H de bajo jitter y de un convertidor analógico digital ADC que trabaja a frecuencias intermedias. El sistema es implementado usando dispositivos comerciales en una placa de circuito impreso diseñada y fabricada, y cuya caracterización experimental muestra una resolución de más 8 bits para un ancho de banda analógico de 20 MHz. Concretamente, la resolución medida será mayor de 9 bits hasta una frecuencia de entrada de 2.9 GHz y mayor de 8 bits para una frecuencia de entrada de hasta 6.5 GHz, lo cual resulta suficiente para cubrir los requerimientos de la mayor parte de los actuales estándares de comunicaciones inalámbricas (GPS, GSM, GPRS, UMTS, Bluetooth, Wi-Fi, WiMAX). Sin embargo, los receptores basados en submuestreo presentan algunos importantes inconvenientes, como son adicionales fuentes de ruido (jitter y plegado de ruido térmico) y una dificultad añadida para implementarlo en escenarios multi-banda y no lineales. Acerca del plegado de ruido en la banda de interés, esta tesis propone el uso de una técnica basada en una arquitectura de reloj múltiple con el objetivo de aumentar la resolución y cubrir un número mayor de estándares para su test y certificación. Empleando una frecuencia de muestreo mayor para el caso del S&H, se conseguirá reducir este efecto, aumentando la resolución en aproximadamente 0.5-1 bit respecto al caso de sólo usar una fuente de reloj. Las expresiones teóricas de esta mejora son desarrolladas y presentadas en esta tesis, siendo posteriormente corroboradas de modo experimental. Por otra parte, esta tesis también propone novedosas técnicas para la aplicación de estos sistemas de submuestreo en entornos multi-banda y no lineales, los cuales presentan desafíos adicionales por el hecho de existir la posibilidad de solapamiento entre la señal de interés y los otros canales de comunicación, así como de solapamiento con sus armónicos. De este modo, esta tesis extiende el uso de los sistemas basados en submuestreo para este tipo de entornos, proponiendo técnicas para la elección de la frecuencia óptima de muestreo que evitan el solapamiento entre señales, a la vez que consiguen incrementar la resolución del receptor. Finalmente, se presentará la optimización en cuanto a características de ruido de un receptor concreto para aplicaciones de banda dual en entornos no lineales. Dicho receptor estará basado en las técnicas de reloj múltiple presentadas anteriormente y en una estructura de multi-filtro entre el S&H y el ADC. El sistema diseñado podrá emplearse para diversas aplicaciones a ambos lados de la cadena de comunicación, tal como en receptores de detección de espectro para radio cognitiva, o implementando el bucle de realimentación de un transmisor para la linealización de amplificadores de potencia. Por tanto, la presente tesis doctoral cuenta con tres contribuciones diferenciadas. La primera de ellas es la dedicada al diseño de un prototipo de recepción multi-estándar basado en submuestreo para aplicaciones de test y certificación. La segunda aportación es la dedicada a la optimización de las especificaciones de ruido a partir de las técnicas presentadas basadas en reloj múltiple. Por último, la tercera contribución principal es la relacionada con la extensión de este tipo de técnicas a sistemas multi-banda en entornos no lineales. Todas estas contribuciones han sido estudiadas teóricamente y experimentalmente validadas

Towards Very Large Scale Analog (VLSA): Synthesizable Frequency Generation Circuits.

Driven by advancement in integrated circuit design and fabrication technologies, electronic systems have become ubiquitous. This has been enabled powerful digital design tools that continue to shrink the design cost, time-to-market, and the size of digital circuits. Similarly, the manufacturing cost has been constantly declining for the last four decades due to CMOS scaling. However, analog systems have struggled to keep up with the unprecedented scaling of digital circuits. Even today, the majority of the analog circuit blocks are custom designed, do not scale well, and require long design cycles. This thesis analyzes the factors responsible for the slow scaling of analog blocks, and presents a new design methodology that bridges the gap between traditional custom analog design and the modern digital design. The proposed methodology is utilized in implementation of the frequency generation circuits – traditionally considered analog systems. Prototypes covering two different applications were implemented. The first synthesized all-digital phase-locked loop was designed for 400-460 MHz MedRadio applications and was fabricated in a 65 nm CMOS process. The second prototype is an ultra-low power, near-threshold 187-500 kHz clock generator for energy harvesting/autonomous applications. Finally, a digitally-controlled oscillator frequency resolution enhancement technique is presented which allows reduction of quantization noise in ADPLLs without introducing spurs.PhDElectrical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttp://deepblue.lib.umich.edu/bitstream/2027.42/109027/1/mufaisal_1.pd

Transmitter architectures with digital modulators, D/A converters and switching-mode power amplifiers

This thesis is composed of nine publications and an overview of the research topic, which also summarises the work. The research described in this thesis focuses on research into the digitalisation of wireless communication base station transmitters. In particular it has three foci: digital modulation, D/A conversion and switching-mode power amplification. The main interest in the implementation of these circuits is in CMOS. The work summarizes the designs of several circuit blocks of a wireless transmitter base station. In the baseband stage, a multicarrier digital modulator that combines multiple modulated signals at different carrier frequencies digitally at baseband, and a multimode digital modulator that can be operated for three different communications standards, are implemented as integrated circuits. The digital modulators include digital power ramping and power level control units for transmission bursts. The upconversion of the baseband signal is implemented using an integrated digital quadrature modulator. The work presented provides insight into the digital-to-analogue interface in the transmitters. This interface is studied both by implementing an intermediate frequency D/A converter in BiCMOS technology and bandpass Delta-Sigma modulator-based D/A conversion in CMOS technology. Finally, the last part of the work discusses switching-mode power amplifiers which are experimented with both as discrete and integrated implementations in conjunction with 1-bit Delta-Sigma modulation and pulse-width modulation as input signal generation methods.Tämä väitöskirja koostuu yhdeksästä julkaisusta ja tutkimusaiheen yhteenvedosta. Väitöskirjassa esitetty tutkimus keskittyy langattaman viestinnän tukiasemien lähettimien digitalisoinnin tutkimukseen. Yksityiskohtaisemmin tutkimusalueet ovat: digitaalinen modulaatio, D/A muunnos ja kytkinmuotoiset tehovahvistimet. Näiden elektronisten piirien toteutuksessa keskitytään CMOS teknologiaan. Työ vetää yhteen useiden langattoman viestinnän tukiasemien lähettimien piirilohkojen suunnittelun. Kantataajuusasteella toteutetaan integroituna piirinä monikantoaaltoinen digitaalinen modulaattori, joka yhdistää useita moduloituja signaaleja eri kantoaalloilla digitaalisesti ja monistandardi digitaalinen modulaatori, joka tukee kolmea eri viestintästandardia. Digitaaliset modulaattoripiirit sisältävät digitaalisen tehoramping ja tehotason säätöyksikön lähetyspurskeita varten. Kantataajuussignaalin ylössekoitus toteutetaan integroitua digitaalista kvadratuurimodulaattoria käyttäen. Esitetty työ antaa näkemystä lähettimien digitalia-analogia rajapintaan, jota tutkitaan toteuttamalla välitaajuinen D/A muunnin BiCMOS teknologialla ja päästökaistainen Delta-Sigma-modulaattoripohjainen D/A muunnin CMOS teknologialla. Lopuksi työn viimeinen osa käsittelee kytkinmuotoisia tehovahvistimia, joita tutkitaan kokeellisesti sekä erilliskompontein toteutettuina piirein että integroiduin piirein toteutettuina käyttäen sisääntulosignaalin muodostamismenetemänä yksibittistä Delta-Sigma-modulaatiota ja pulssin leveys modulaatiota.reviewe

A low power prescaler, phase frequency detector, and charge pump for a 12 ghz frequency synthesizer

A low power implementation of a CMOS frequency synthesizer at 12 GHz is an important step to improve the efficiency of a wireless transceiver in this frequency band. Since synthesizers are often employed as reference frequency sources such as local oscillators for up or down-conversion in communications system, their design is especially important for high performance transceiver applications. CMOS PLLs operating at high frequencies consume large amounts of power for proper operation, making power efficiency a top priority in transciever implementation. In response, this thesis presents a low power phase and frequency detector with True Single Phase Clocking by employing the .18μ TSMC process with a 1.8 V supply voltage. A conventional but extremely power efficient nano-watt charge pump is also implemented for additional power savings. Furthermore, a state of the art 16/17 prescaler using Current Mode Logic (CML) D-Flip Flops, CMOS inverters, and transmission gates has been optimized for maximum power savings. The prescaler consists of a 4/5 synchronous core and a feedback loop which modulates the 4/5 core to produce a division ratio of 16/17. Instead of employing power hungry CML, the feedback circuit takes advantage of low power NOR and AND gates realized in Transmission Gate Logic (TGL) to reduce the power consumption. To the best of my knowledge, this technique has never been used in a high frequency prescaler before