Theory of super power saving circuits and configurations for mixed signal CPU for smartcard application / Teori om extremt energisparande kretsar och konfigurationer för mixed signal CPU för smartcard applikation

Kleist, Anders

January 2004

Designing an application specific integrated circuit (ASIC) must be starting with careful preparations, otherwise the chip will not be as good as possible. The theoretical studies must cover everything from the chip circuits to the application structure. In mobile applications there is extremely important that the current consumption becomes minimized because the battery power is limited. The power reductions studies must include the most power costing circuits on the chip. When the whole circuit or segments of the circuit is not in use, they must switch fast and simple into another mode that consume nearly none power. This mode is called sleep-mode. If the sleep-mode has very low leakage currents, the lifetime of the application will dramatically increase. This report studies the most power costing circuits in smartcard application ASIC. The chip should be used to control a LCD display on the smartcard. The circuits that have been investigated are level shifters, charge pumps and LCD drivers, also sleep-mode configuration possibilities have been investigated. Other small preparing work is also included in the thesis.

Electronics

charge pump

sleep-mode

level shifter

cholesteric

liquid crystal

smartcard

DC-DC converter

MTCMOS

display driving

assembler

voltage doubler

low power

Elektronik

Electronics

Elektronik

Oscillation Control in CMOS Phase-Locked Loops

Terlemez, Bortecene

22 November 2004

Recent advances in voltage-controlled oscillator (VCO) design and the trend of CMOS processing indicate that the oscillator control is quickly becoming one of the forefront problems in high-frequency and low-phase-noise phase-locked loop (PLL) design. This control centric study explores the limitations and challenges in high-performance analog charge-pump PLLs when they are extended to multiple gigahertz applications. Several problems with performance enhancement and precise oscillator control using analog circuits in low-voltage submicron CMOS processes, coupled with the fact that analog (or semi-digital) oscillators having various advantages over their digitally controlled counterparts, prompted the proposal of the digitally-controlled phase-locked loop. This research, then, investigates a class of otherwise analog PLLs that use a digital control path for driving a current-controlled oscillator. For this purpose, a novel method for control digitization is described where trains of pulses code the phase/frequency comparison information rather than the duration of the pulses: Pulse-Stream Coded Phase-Locked Loop (psc-PLL). This work addresses issues significant to the design of future PLLs through a comparative study of the proposed digital control path topology and improved cutting-edge charge-pump PLLs.

Charge pump

PLL

Phase-locked loops

Mixed-signal circuits

Voltage-controlled oscillators

Digital electronics

Digital-to-analog converters

Design of CMOS integrated phase-locked loops for multi-gigabits serial data links

Cheng, Shanfeng

25 April 2007

High-speed serial data links are quickly gaining in popularity and replacing the conventional parallel data links in recent years when the data rate of communication exceeds one gigabits per second. Compared with parallel data links, serial data links are able to achieve higher data rate and longer transfer distance. This dissertation is focused on the design of CMOS integrated phase-locked loops (PLLs) and relevant building blocks used in multi-gigabits serial data link transceivers. Firstly, binary phase-locked loops (BPLLs, i.e., PLLs based on binary phase detectors) are modeled and analyzed. The steady-state behavior of BPLLs is derived with combined discrete-time and continuous-time analysis. The jitter performance characteristics of BPLLs are analyzed. Secondly, a 10 Gbps clock and data recovery (CDR) chip for SONET OC- 192, the mainstream standard for optical serial data links, is presented. The CDR is based on a novel referenceless dual-loop half-rate architecture. It includes a binary phase-locked loop based on a quad-level phase detector and a linear frequency-locked loop based on a linear frequency detector. The proposed architecture enables the CDR to achieve large locking range and small jitter generation at the same time. The prototype is implemented in 0.18 μm CMOS technology and consumes 250 mW under 1.8 V supply. The jitter generation is 0.5 ps-rms and 4.8 ps-pp. The jitter peaking and jitter tolerance performance exceeds the specifications defined by SONET OC-192 standard. Thirdly, a fully-differential divide-by-eight injection-locked frequency divider with low power dissipation is presented. The frequency divider consists of a four-stage ring of CML (current mode logic) latches. It has a maximum operating frequency of 18 GHz. The ratio of locking range over center frequency is up to 50%. The prototype chip is implemented in 0.18 μm CMOS technology and consumes 3.6 mW under 1.8 V supply. Lastly, the design and optimization techniques of fully differential charge pumps are discussed. Techniques are proposed to minimize the nonidealities associated with a fully differential charge pump, including differential mismatch, output current variation, low-speed glitches and high-speed glitches. The performance improvement brought by the techniques is verified with simulations of schematics designed in 0.35 μm CMOS technology.

Phase-locked Loops

PLL

Clock and Data Recovery

CDR

Jitter

Phase Noise

VCO

Charge Pump

Phase Detector

Frequency Detector

Voltage-Controlled Oscillator

Low noise, low power interface circuits and systems for high frequency resonant micro-gyroscopes

Dalal, Milap

03 July 2012

Today's state-of-the-art rate vibratory gyroscopes use a large proof mass that vibrates at a low resonance frequency (3-30 kHz), a condition that creates a performance tradeoff in which the gyroscope can either offer large bandwidth or high resolution, but not both. This tradeoff led to the development of the capacitive bulk acoustic wave (BAW) silicon disk gyroscope, a new class of micromachined rate vibratory gyroscopes operating in the frequency range of 1-10MHz with high device bandwidth and shock/vibration tolerance. By scaling the frequency, BAW gyroscopes can provide low mechanical noise without sacrificing the high bandwidth performance needed for most commercial applications. The drive loop of the BAW gyroscope can also be exploited as a timing device that can be integrated in existing commercial systems to provide competitive clock performance to the state-of-the-art using less area and power. This dissertation discusses the design and implementation of a CMOS ASIC architecture that interfaces with a high-Q, wide-bandwidth BAW gyroscope and the challenges associated with optimizing the noise performance to achieve navigation-grade levels of sensitivity as the frequency is scaled into the MHz regime. Mathematical models are derived to describe the operation of the sensor and are used to generate equivalent electrical circuit models of the gyroscope. A design strategy is then outlined for the ASIC to optimize the drive loop and sense channel for power and noise, and steps toward reducing this noise as the system is pushed to navigation-grade performance are presented that maintain optimum system power consumption. After analyzing the BAW gyroscope and identifying a strategy for developing the drive and sense interface circuitry, a complete fully-differential ASIC is designed in 0.18μm CMOS to interface with a bulk acoustic wave (BAW) disk gyroscope. As an oscillator, the gyroscope provides an uncompensated clock signal at ~9.64 MHz with a temperature sensitivity of -27 ppm/°C and phase noise of -104 dBc at 1 kHz from carrier. When the complete ASIC is interfaced with the gyroscope, the sensor shows a measured rate sensitivity of 1.15 mV/o/s with an open-loop bandwidth of 280 Hz and a bias instability of 0.095 o/s, suitable for the rate-grade performance commonly required for commercial and consumer electronics applications. The system is recorded to have a total power of 1.6 mW and a total area of 0.64 mm2. Following the design of the interface ASIC, this dissertation investigates in further detail the requirements for designing and optimizing charge pumps for capacitive MEMS devices. Basic charge pump design is outlined, followed by an overview of techniques that can be used to generate larger polarization voltages from the ASIC. Lastly, an alternate measurement technique for measuring the rotation rate of the gyroscope is discussed. This technique is based on the phase-shift modulation of the gyroscope output signal when the device is driven with two orthogonal signal inputs and can be easily modified to provide either linear scale factor measurement or a linear calibration curve that can be used to track and adjust the variation of the sensor scale factor over time.

IMU

Inertial sensor

Phase-shift readout

Amplitude readout

Charge pump

MEMS gyroscope

Interface ASIC

Noise and power optimization

Interface circuits

Gyroscopes

Microelectromechanical systems

Effect of DC to DC converters on organic solar cell arrays for powering DC loads

Trotter, Matthew S.

26 February 2009

The objective of this research is to determine if it is possible to reduce the number of organic solar cells required to power a load using a DC to DC converter thereby reducing the cost of the organic solar array system. An organic solar power system designer may choose an organic implementation of a DC to DC converter to go along with the organic solar cell array. Common DC to DC converters include the buck converter, boost converter, buck/boost converter, and Cuk converter, all of which are not good candidates for organic implementation due to their use of inductors. Organic inductors are relatively more lossy than organic capacitors. So, an inductor-less DC to DC converter, such as the Dickson charge pump, would be a better candidate for organic implementation. Solar cells connected in an array configuration usually do not perform up to their full potential due to current and voltage mismatches between solar cells. These mismatches can be related to each solar cell's circuit model parameters such as the photon current density, diode ideality factor, diode reverse saturation current density, parallel resistance, and series resistance. This research varies these circuit model parameters as dependent variables, and observes the loads and power levels that make the Dickson charge pump a feasible option. The results show that current mismatch does produce an opportunity to use a DC to DC converter to save the use of a few solar cells. However, the Dickson charge pump was found to be infeasible due to an input voltage requirement that could not be met using the tested organic solar cells.

DC to DC converters

Charge pumps

Organic solar cells

Solar cells

Dickson charge pump

Solar batteries

DC-to-DC converters

Organic electronics

Low-voltage and low-power libraries for Medical SoCs

Balasubramanian, Sidharth

January 2009

No description available.

Electrical Engineering

analog circuits

vlsi

rail-to-rail

rail-rail

chopper amplifier

dickson charge pump

sar adc

data conversion

medical socs

biochips

biosignals

voltage references

MOS

Low Power And Low Spur Frequency Synthesizer Circuit Techniques For Energy Efficient Wireless Transmitters

Manikandan, R R

09 1900

There has been a huge rise in interest in the design of energy efficient wireless sensor networks (WSN) and body area networks (BAN) with the advent of many new applications over the last few decades. The number of sensor nodes in these applications has also increased tremendously in the order of few hundreds in recent years. A typical sensor node in a WSN consists of circuits like RF transceivers, micro-controllers or DSP, ADCs, sensors, and power supply circuits. The RF transmitter and receiver circuits mainly the frequency synthesizers(synthesis of RF carrier and local oscillator signals in transceivers) consume a significant percentage of its total power due to its high frequency of operation. A charge-pump phase locked loop (CP-PLL) is the most commonly used frequency synthesizer architecture in these applications. The growing demands of WSN applications, such as low power consumption larger number of sensor nodes, single chip solution, and longer duration operation presents several design challenges for these transmitter and frequency synthesizer circuits in these applications and a few are listed below, Low power frequency synthesizer and transmitter designs with better spectral performance is essential for an energy efficient operation of these applications. The spurious tones in the frequency synthesizer output will mix the interference signals from nearby sensor nodes and from other interference sources present nearby ,to degrade the wireless transmitter and receiver performance[1]. With the increased density of sensor nodes (more number of in-band interference sources) and degraded performance of analog circuits in the nano-meter CMOS process technologies, the spur reduction techniques are essential to improve the performance of frequency synthesizers in these applications. A single chip solution of sensor nodes with its analog and digital circuits integrated on the same die is preferred for its low power, low cost, and reduced size implementation. However, the parasitic interactions between these analog and digital sub-systems integrated on a common substrate, degrade the spectral performance of frequency synthesizers in these implementations[2]. Therefore, techniques to improve the mixed signal integration performance of these circuits are in great demand. In this thesis, we present a custom designed energy efficient 2.4 GHz BFSK/ASK transmitter architecture using a low power frequency synthesizer design technique taking advantage of the CMOS technology scaling benefits. Furthermore, a few design guidelinesandsolutionstoimprovethespectralperformanceoffrequency synthesizer circuits and in-turn the performance of transmitters are also presented. The target application being short distance, low power, and battery operated wireless communication applications. The contributions in this thesis are, Spectral performance improvement techniques The CP mismatch current is a dominant source of reference spurs in the nano-meter CMOS PLL implementations due to its worsened channel length modulation effect [3]. In this work, we present a CP mismatch current calibration technique using an adaptive body bias tuning of its PMOS transistors. Chip prototype of 2.4 GHzCP-PLLwith the proposed CP calibration technique was fabricated in UMC 0.13 µm CMOS process. Measurements show a CP mismatch current of less than 0.3 µA(0.55 %) using the proposed calibration technique over the VCO control voltage range 0.3 to 1 V. The closed loop PLL measurements using the proposed technique exhibited a 9dB reduction in the reference spur levels across the PLL output frequency range 2.4 -2.5 GHz. The parasitic interactions between analog and digital circuits through the common substrate severely affects the performance of CP-PLLs. In this work, we experimentally demonstrate the effect of periodic switching noise generated from the digital buffers on the performance of charge-pump PLLs. The sensitivity of PLL performance metrics such as output spur level, phase noise, and output jitter are monitored against the variations in the properties of a noise injector digital signal. Measurements from a 500 MHz CP-PLL shows that the pulsed noise injection with the duty cycle of noise injector signal reduced from 50% to 20%, resulted in a 12.53 dB reduction in its output spur level and a 107 ps reduction in its Pk-Pk deterministic period jitter performance. Low power circuit techniques A low power frequency synthesizer design using a digital frequency multiplication technique is presented. The proposed frequency multiply by 3 digital edge combiner design having a very few logic gates, demonstrated a significant reduction in the power consumption of frequency synthesizer circuits, with an acceptable spectral performance suitable for these relaxed performance applications. A few design guidelines and techniques to further improve its spectral performance are also discussed and validated through simulations. Chip prototypes of 2.4 GHz CP-PLLs with and without digital frequency multiplier circuits are fabricated in UMC 0.13 µm CMOS process. The 2.4 GHz CP-PLL using the proposed digital frequency multiplication technique (10.7 mW) consumed a much reduced power compared to a conventional implementation(20.3 mW). A custom designed, energy efficient 2.4 GHz BFSK/ASK transmitter architecture using the proposed low power frequency synthesizer design technique is presented. The transmitter uses a class-D power amplifier to drive the 50Ω antenna load. Spur reduction techniques in frequency synthesizers are also used to improve the spectral performance of the transmitter. A chip prototype of the proposed transmitter architecture was implemented in UMC0.13 µm CMOS process. The transmitter consume14 mA current from a 1.3V supply voltage and achieve improved energy efficiencies of 0.91 nJ/bit and 6.1 nJ/bit for ASK and BFSK modulations with data rates 20Mb/s & 3Mb/s respectively.

Transmitter Architecture

Energy Efficient Wireless Transmitters

Wireless Sensor Networks

Phase-Locked Loop (PLL)

Frequency Synthesizer Circuits

Wireless Communication

Charge Pump Phase-Locked Loop (CP-PLL)

Analog Integrated Circuits

Charge Pump Circuits

Electronic Circuits

Spur Suppression Technique

Energy Efficient Transmitters

Communication Engineering

Conception de circuits mémoires flash pour plateforme ultra faible consommation / Flash memory circuit design for ultra-low power platform

Ngueya Wandji, Steve

15 December 2017

Le marché des objets connectés sécurisés est en plein essor et nécessite des plateformes de développement faible consommation pour des applications sans contact dans des facteurs de forme réduits. La réduction du facteur de forme impacte l’antenne et entraîne une baisse de l’énergie disponible dans la puce, qui, pour travailler à performances égales, doit voir sa consommation diminuer drastiquement. Un des principaux contributeurs à la consommation est la mémoire non-volatile embarquée (eNVM) utilisée pour le stockage et l’exécution du code. Il faut donc, pour une technologie donnée, être capable de concevoir des blocs périphériques du plan mémoire de manière à réduire la consommation au maximum. L’objectif de la thèse est donc de sélectionner une technologie eNVM très faible consommation compatible avec le procédé technologie CMOS classique, d’identifier les blocs critiques lors des opérations de la mémoire, et enfin de proposer des solutions de minimisation de la consommation pour chaque bloc critique. Pour ce faire, une étude de toutes les mémoires non volatiles embarquées disponibles sur le marché est réalisée. Il en ressort que la technologie Flash, en particulier la Flash NOR embarquée de type SuperFlash® ESF3, est la mieux adaptée pour les systèmes télé-alimentés. L’étude de la macro Flash NOR montre que durant l’écriture et l’effacement, la consommation du système est en partie liée à la génération de la haute tension par les pompes de charge. Par contre, durant la lecture, les performances globales du système sont déterminées par l’amplificateur de lecture. Ainsi, un travail de conception de chaque bloc individuel est mis en oeuvre pour réduire la consommation. / The market of secure connected devices is booming and requires low power development platforms for contactless applications in reduced form factors. The reduction in the form factor impacts the antenna size and thus leads to a decrease of the energy available in the chip, which should reduce drastically its consumption while keeping performances. One of the main contributors to the chip consumption is the embedded non-volatile memory (eNVM) used for storage and code execution. Therefore, for a given technology, it is necessary to design peripheral blocks of the memory array under strong consumption constraints. The aim of the thesis is to select a very low-power embedded nonvolatile memory technology compatible with the classical CMOS process, to identify the critical blocks during the operations of the memory, and finally to propose solutions to minimize the power consumption of each critical block.In order to do this, a study of all the embedded non-volatile memories available on the market is carried out. It emerges that the Flash technology, in particular the SuperFlash® ESF3 based NOR Flash technology, is best suited for remote-powered systems. The study of the NOR Flash macrocell shows that during write and erase operations, the system consumption is mainly related to the high voltage generation by charge pumps. However, during a read operation, overall performances of the system is determined by the sense amplifier. A design work for each individual block is then implemented to reduce consumption.

Cartes à puce

Mémoires non volatiles

Mémoire Flash embarquée

Pompe de charge

Amplificateur de lecture

Recyclage de charges

Faible consommation

Smartcards

Non-Volatile memories

Embedded Flash memory

Charge pump

Sense amplifier

Charge recycling

Low power

Entwicklung einer monolithisch integrierten 2,44 GHz Phasenregelschleife in der LFoundry 150nm-CMOS Technologie

Scheibe, Niko

25 November 2010

Die Spezifikationen und Toleranzbereiche heutiger Hochgeschwindigkeitsdatenübertragungstechnologien nehmen immer weiter an Komplexität, aufgrund der steigenden Informationsmenge, zu. Zur Verarbeitung von Daten in Frequenzbereichen oberhalb von einem Gigahertz sind Referenzsignale notwendig, welche ein äußerst geringes Phasenrauschen aufweisen um benachbarte Kanäle nicht zu beeinflussen. Diese Referenzsignale werden in Mischerschaltungen zur Modulation oder Demodulation zwischen radio frequency (RF)- und intermediate frequency (IF)-Signalen verwendet. Die benötigte Signalform ist eine Sinusschwingung, die nicht durch digitale Schaltungsblöcke erzeugt werden kann. Daher ist die Notwendigkeit von analogen LC-Oszillatoren gegeben. Die Erzeugung von höchst stabilen und hochfrequenten Signalen war lange Zeit teuren Silizium-Germanium-Technologien vorbehalten. Jedoch erfordert der steigende Integrationsgrad und der hart umkämpfte Markt, die Entwicklung von RF-Schaltungen in günstigen CMOS-Technologien. In Zusammenarbeit mit der Landshut Silicon Foundry soll dazu eine monolithisch integrierte Phase-Locked Loop (PLL) mit einer mittleren Ausgangsfrequenz von 2,44 GHz und einem Phasenrauschen kleiner -115 dBc/Hz bei einem Abstand von 1 MHz vom Träger entwickelt werden. Dabei wird das Hauptaugenmerk auf den Kern der PLL gelegt, welcher einen spannungsgesteuerten Oszillator, einen Phasen-/Frequenzdetektor, eine Ladungspumpe, einen Schleifenfilter und einen Frequenzteiler beinhaltet. Außerdem sollen Testszenarien vorgestellt werden, um die Eigenschaften der gefertigten PLL zu bestimmen und zu vergleichen.

PLL

Phasenregelschleife

Schleifenfilter

Frequenzteiler

Phasendetektor

LFoundry

Ladungspumpe

spannungsgesteuerter Oszillator

PLL

phase-locked loop

loopfilter

frequency divider

phase detetector

LFoundry

charge pump

voltage controlled oszillator

VCO

ddc:500

Phasenregelkreis

VCO

Entwicklung einer monolithisch integrierten 2,44 GHz Phasenregelschleife in der LFoundry 150nm-CMOS Technologie

Scheibe, Niko

30 August 2010

Die Spezifikationen und Toleranzbereiche heutiger Hochgeschwindigkeitsdatenübertragungstechnologien nehmen immer weiter an Komplexität, aufgrund der steigenden Informationsmenge, zu. Zur Verarbeitung von Daten in Frequenzbereichen oberhalb von einem Gigahertz sind Referenzsignale notwendig, welche ein äußerst geringes Phasenrauschen aufweisen um benachbarte Kanäle nicht zu beeinflussen. Diese Referenzsignale werden in Mischerschaltungen zur Modulation oder Demodulation zwischen radio frequency (RF)- und intermediate frequency (IF)-Signalen verwendet. Die benötigte Signalform ist eine Sinusschwingung, die nicht durch digitale Schaltungsblöcke erzeugt werden kann. Daher ist die Notwendigkeit von analogen LC-Oszillatoren gegeben. Die Erzeugung von höchst stabilen und hochfrequenten Signalen war lange Zeit teuren Silizium-Germanium-Technologien vorbehalten. Jedoch erfordert der steigende Integrationsgrad und der hart umkämpfte Markt, die Entwicklung von RF-Schaltungen in günstigen CMOS-Technologien. In Zusammenarbeit mit der Landshut Silicon Foundry soll dazu eine monolithisch integrierte Phase-Locked Loop (PLL) mit einer mittleren Ausgangsfrequenz von 2,44 GHz und einem Phasenrauschen kleiner -115 dBc/Hz bei einem Abstand von 1 MHz vom Träger entwickelt werden. Dabei wird das Hauptaugenmerk auf den Kern der PLL gelegt, welcher einen spannungsgesteuerten Oszillator, einen Phasen-/Frequenzdetektor, eine Ladungspumpe, einen Schleifenfilter und einen Frequenzteiler beinhaltet. Außerdem sollen Testszenarien vorgestellt werden, um die Eigenschaften der gefertigten PLL zu bestimmen und zu vergleichen.

info:eu-repo/classification/ddc/500

ddc:500

Phasenregelkreis

VCO