8 research outputs found
Architectural Alternatives to Implement High-Performance Delta-Sigma Modulators
RÉSUMÉ Le besoin d’appareils portatifs, de téléphones intelligents et de systèmes microélectroniques implantables médicaux s’accroît remarquablement. Cependant, l’optimisation de l’alimentation de tous ces appareils électroniques portables est l’un des principaux défis en raison du manque de piles à grande capacité utilisées pour les alimenter. C’est un fait bien établi que le convertisseur analogique-numérique (CAN) est l’un des blocs les plus critiques de ces appareils et qu’il doit convertir efficacement les signaux analogiques au monde numérique pour effectuer un post-traitement tel que l’extraction de caractéristiques. Parmi les différents types de CAN, les modulateurs Delta Sigma (��M) ont été utilisés dans ces appareils en raison des fonctionnalités alléchantes qu’ils offrent. En raison du suréchantillonnage et pour éloigner le bruit de la bande d’intérêt, un CAN haute résolution peut être obtenu avec les architectures ��. Il offre également un compromis entre la fréquence d’échantillonnage et la résolution, tout en offrant une architecture programmable pour réaliser un CAN flexible. Ces CAN peuvent être implémentés avec des blocs analogiques de faible précision. De plus, ils peuvent être efficacement optimisés au niveau de l’architecture et circuits correspondants. Cette dernière caractéristique a été une motivation pour proposer différentes architectures au fil des ans. Cette thèse contribue à ce sujet en explorant de nouvelles architectures pour optimiser la structure ��M en termes de résolution, de consommation d’énergie et de surface de silicium. Des soucis particuliers doivent également être pris en compte pour faciliter la mise en œuvre du ��M. D’autre part, les nouveaux procédés CMOS de conception et fabrication apportent des améliorations remarquables en termes de vitesse, de taille et de consommation d’énergie lors de la mise en œuvre de circuits numériques. Une telle mise à l’échelle agressive des procédés, rend la conception de blocs analogiques tel que un amplificateur de transconductance opérationnel (OTA), difficile. Par conséquent, des soins spéciaux sont également pris en compte dans cette thèse pour surmonter les problèmes énumérés. Ayant mentionné ci-dessus que cette thèse est principalement composée de deux parties principales. La première concerne les nouvelles architectures implémentées en mode de tension et la seconde partie contient une nouvelle architecture réalisée en mode hybride tension et temps.----------ABSTRACT The need for hand-held devices, smart-phones and medical implantable microelectronic sys-tems, is remarkably growing up. However, keeping all these electronic devices power optimized is one of the main challenges due to the lack of long life-time batteries utilized to power them up. It is a well-established fact that analog-to-digital converter (ADC) is one of the most critical building blocks of such devices and it needs to efficiently convert analog signals to the digital world to perform post processing such as channelizing, feature extraction, etc. Among various type of ADCs, Delta Sigma Modulators (��Ms) have been widely used in those devices due to the tempting features they offer. In fact, due to oversampling and noise-shaping technique a high-resolution ADC can be achieved with �� architectures. It also offers a compromise between sampling frequency and resolution while providing a highly-programmable approach to realize an ADC. Moreover, such ADCs can be implemented with low-precision analog blocks. Last but not the least, they are capable of being effectively power optimized at both architectural and circuit levels. The latter has been a motivation to proposed different architectures over the years.This thesis contributes to this topic by exploring new architectures to effectively optimize the ��M structure in terms of resolution, power consumption and chip area. Special cares must also be taken into account to ease the implementation of the ��M. On the other hand, advanced node CMOS processes bring remarkable improvements in terms of speed, size and power consumption while implementing digital circuits. Such an aggressive process scaling, however, make the design of analog blocks, e.g. operational transconductance amplifiers (OTAs), cumbersome. Therefore, special cares are also taken into account in this thesis to overcome the mentioned issues. Having had above mentioned discussion, this thesis is mainly split in two main categories. First category addresses new architectures implemented in a pure voltage domain and the second category contains new architecture realized in a hybrid voltage and time domain. In doing so, the thesis first focuses on a switched-capacitor implementation of a ��M while presenting an architectural solution to overcome the limitations of the previous approaches. This limitations include a power hungry adder in a conventional feed-forward topology as well as power hungry OTAs
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Wide-bandwidth, high-resolution delta-sigma analog-to-digital converters
There is a significant need in recent mobile communication and wireless broadband
systems for high-performance analog-to-digital converters (ADCs) that have wide
bandwidth (BW>5-MHz) and high data rate (>100-Mbps). A delta-sigma ADC is
recognized as a power-efficient ADC architecture when high resolution (>12-b) is
required. This is due to several advantages of the delta-sigma ADC including relaxed
anti-aliasing filter requirements, high signal-to-noise and distortion ratio (SNDR) and
most importantly, reduced sensitivity to analog imperfections. In this thesis, several
structures and design techniques are developed for the implementation of continuoustime
(CT) and discrete-time (DT) delta-sigma ADCs. These techniques save the total
power consumption, reduce the design complexity, and decrease the chip die area of
delta-sigma modulators.
First a 4th-order single stage CT delta-sigma ADC with a novel single-amplifier-biquad
(SAB) based loop filter is presented. By utilizing the SAB networks in the loop filter of
an Nth-order CT delta-sigma modulator, it requires only half the number of active
amplifiers and feed-forward branches used in the conventional modulator architecture,
thus decreasing the power consumption and area by reducing the number of amplifiers.
The proposed scheme also enables the modulator to use a switch-capacitor (SC) adder
due to the reduced number of feedforward branches to its summing block. As a sequence,
it consumes less power compared to a conventional CT adder. With a 130-nm CMOS
technology, the fabricated prototype IC achieves a dynamic range of 80 dB with 10 MHz
signal bandwidth and analog power dissipation lower than 12 mW. Presented as the
second scheme to save power consumption and chip die area in ΔΣ modulators is a new
stage-sharing technique in a discrete-time 2-2 MASH ΔΣ ADC. The proposed technique
shares all the active blocks of the modulator second stage with its first stage during the
two non-overlapping clock phases. Measurement results show that the modulator
designed in a 0.13-um CMOS technology achieves 76 dB SNDR over a 10 MHz
conversion bandwidth dissipating less than 9 mW analog power
Low Power Analog to Digital Converters in Advanced CMOS Technology Nodes
The dissertation presents system and circuit solutions to improve the power efficiency and address high-speed design issues of ADCs in advanced CMOS technologies.
For image sensor applications, a high-performance digitizer prototype based on column-parallel single-slope ADC (SS-ADC) topology for readout of a back-illuminated 3D-stacked CMOS image sensor is presented. To address the high power consumption issue in high-speed digital counters, a passing window (PW) based hybrid counter topology is proposed. To address the high column FPN under bright illumination conditions, a double auto-zeroing (AZ) scheme is proposed. The proposed techniques are experimentally verified in a prototype chip designed and fabricated in the TSMC 40 nm low-power CMOS process. The PW technique saves 52.8% of power consumption in the hybrid digital counters. Dark/bright column fixed pattern noise (FPN) of 0.0024%/0.028% is achieved employing the proposed double AZ technique for digital correlated double sampling (CDS). A single-column digitizer consumes total power of 66.8μW and occupies an area of 5.4 µm x 610 µm.
For mobile/wireless receiver applications, this dissertation presents a low-power wide-bandwidth multistage noise-shaping (MASH) continuous-time delta-sigma modulator (CT-ΔΣM) employing finite impulse response (FIR) digital-to-analog converters (DACs) and encoder-embedded loop-unrolling (EELU) quantizers. The proposed MASH 1-1-1 topology is a cascade of three single-loop first-order CT-ΔΣM stages, each of which consists of an active-RC integrator, a current-steering DAC, and an EELU quantizer. An FIR filter in the main 1.5-bit DAC improves the modulator’s jitter sensitivity performance. FIR’s effect on the noise transfer function (NTF) of the modulator is compensated in the digital domain thanks to the MASH topology. Instead of employing a conventional analog direct feedback path, a 1.5-bit EELU quantizer based on multiplexing comparator outputs is proposed; this approach is suitable for highspeed operation together with power and area benefits. Fabricated in a 40-nm low-power CMOS technology, the modulator’s prototype achieves a 67.3 dB of signal-to-noise and distortion ratio (SNDR), 68 dB of signal-to-noise ratio (SNR), and 68.2 dB of dynamic range (DR) within 50.5 MHz of bandwidth (BW), while consuming 19 mW of total power (P). The proposed modulator features 161.5 dB of figure-of-merit (FOM), defined as FOM = SNDR + 10 log10 (BW/P)
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
Analysis of Current Conveyor based Switched Capacitor Circuits for Application in ∆Σ Modulators
The reduction in supply voltage, loss of dynamic range and increased noise prevent the analog circuits from taking advantage of advanced technologies. Therefore the trend is to move all signal processing tasks to digital domain where advantages of technology scaling can be used. Due to this, there exists a need for data converters with large signal bandwidths, higher speeds and greater dynamic range to act as an interface between real world analog and digital signals.
The Delta Sigma (∆Σ) modulator is a data converter that makes use of large sampling rates and noise shaping techniques to achieve high resolution in the band of interest. The modulator consists of analog integrators and comparators which create a modulated digital bit stream whose average represents the input value. Due to their simplicity, they are popular in narrow band receivers, medical and sensor applications.
However Operational Amplifiers (Op-Amps) or Operational Transconductance Amplifiers (OTAs), which are commonly used in data converters, present a bottleneck. Due to low supply voltages, designers rely on folded cascode, multistage cascade and bulk driven topologies for their designs. Although the two stage or multistage cascade topologies offer good gain and bandwidth, they suffer from stability problems due to multiple stages and feedback requiring large compensation capacitors. Therefore other low voltage Switched-Capacitor (SC) circuit techniques were developed to overcome these problems, based on inverters, comparators and unity gain buffers.
In this thesis we present an alternative approach to design of ∆Σ modulators using Second Generation Current Conveyors (CCIIs). The important feature of these modulators is the replacement of the traditional Op-Amp based SC integrators with CCII based SC integrators. The main design issues such as the effect of the non-idealities in the CCIIs are considered in the operation of SC circuits and solutions are proposed to cancel them. Design tradeoffs and guidelines for various components of the circuit are presented through analysis of existing and the proposed SC circuits. A two step adaptive calibration technique is presented which uses few additional components to measure the integrator input output characteristic and linearize it for providing optimum performance over a wide range of sampling frequencies while maintaining low power and area.
The presented CCII integrator and calibration circuit are used in the design of a 4th order (2-2 cascade) ∆Σ modulator which has been fabricated in UMC 90nm/1V technology through Europractice. Experimental values for Signal to Noise+Distortion Ratio (SNDR), Dynamic Range (DR) and Figure Of Merit (FOM) show that the modulator can compete with state of art reconfigurable Discrete-Time (DT) architectures while using lower gain stages and less design complexity
Data acquisition techniques based on frequency-encoding applied to capacitive MEMS microphones
Mención Internacional en el tÃtulo de doctorThis thesis focuses on the development of capacitive sensor readout circuits
and data converters based on frequency-encoding. This research
has been motivated by the needs of consumer electronics industry, which
constantly demands more compact readout circuit for MEMS microphones
and other sensors. Nowadays, data acquisition is mainly based
on encoding signals in voltage or current domains, which is becoming
more challenging in modern deep submicron CMOS technologies.
Frequency-encoding is an emerging signal processing technique based
on encoding signals in the frequency domain. The key advantage of
this approach is that systems can be implemented using mostly-digital
circuitry, which benefits from CMOS technology scaling. Frequencyencoding
can be used to build phase referenced integrators, which can
replace classical integrators (such as switched-capacitor based integrators)
in the implementation of efficient analog-to-digital converters and
sensor interfaces. The core of the phase referenced integrators studied in
this thesis consists of the combination of different oscillator topologies
with counters and highly-digital circuitry.
This work addresses two related problems: the development of capacitive
MEMS sensor readout circuits based on frequency-encoding, and the
design and implementation of compact oscillator-based data converters
for audio applications.
In the first problem, the target is the integration of the MEMS sensor
into an oscillator circuit, making the oscillation frequency dependent on
the sensor capacitance. This way, the sound can be digitized by measuring
the oscillation frequency, using digital circuitry. However, a MEMS
microphone is a complex structure on which several parasitic effects can
influence the operation of the oscillator. This work presents a feasibility
analysis of the integration of a MEMS microphone into different oscillator
topologies. The conclusion of this study is that the parasitics of the
MEMS limit the performance of the microphone, making it inefficient.
In contrast, replacing conventional ADCs with frequency-encoding based
ADCs has proven a very efficient solution, which motivates the next
problem.
In the second problem, the focus is on the development of high-order
oscillator-based Sigma-Delta modulators. Firstly, the equivalence between classical
integrators and phase referenced integrators has been studied, followed
by an overview of state-of-art oscillator-based converters. Then,
a procedure to replace classical integrators by phase referenced integrators
is presented, including a design example of a second-order oscillator based
Sigma-Delta modulator. Subsequently, the main circuit impairments that
limit the performance of this kind of implementations, such as phase
noise, jitter or metastability, are described.
This thesis also presents a methodology to evaluate the impact of
phase noise and distortion in oscillator-based systems. The proposed
method is based on periodic steady-state analysis, which allows the rapid
estimation of the system dynamic range without resorting to transient
simulations. In addition, a novel technique to analyze the impact of
clock jitter in Sigma-Delta modulators is described.
Two integrated circuits have been implemented in 0.13 μm CMOS
technology to demonstrate the feasibility of high-order oscillator-based Sigma-Delta modulators. Both chips have been designed to feature secondorder
noise shaping using only oscillators and digital circuitry. The first
testchip shows a malfunction in the digital circuitry due to the complexity
of the multi-bit counters. The second chip, implemented using
single-bit counters for simplicity, shows second-order noise shaping and
reaches 103 dB-A of dynamic range in the audio bandwidth, occupying
only 0.04 mm2.Esta tesis se centra en el desarrollo de conversores de datos e interfaces
para sensores capacitivos basados en codificación en frecuencia. Esta
investigación está motivada por las necesidades de la industria, que constantemente
demanda reducir el tamaño de este tipo de circuitos. Hoy en
dÃa, la adquisición de datos está basada principalmente en la codificación
de señales en tensión o en corriente. Sin embargo, la implementación
de este tipo de soluciones en tecnologÃas CMOS nanométricas presenta
varias dificultades.
La codificación de frecuencia es una técnica emergente en el procesado
de señales basada en codificar señales en el dominio de la frecuencia.
La principal ventaja de esta alternativa es que los sistemas pueden implementarse
usando circuitos mayoritariamente digitales, los cuales se
benefician de los avances de la tecnologÃa CMOS. La codificación en
frecuencia puede emplearse para construir integradores referidos a la
fase, que pueden reemplazar a los integradores clásicos (como los basados
en capacidades conmutadas) en la implementación de conversores
analógico-digital e interfaces de sensores. Los integradores referidos a la
fase estudiados en esta tesis consisten en la combinación de diferentes
topologÃas de osciladores con contadores y circuitos principalmente digitales.
Este trabajo aborda dos cuestiones relacionadas: el desarrollo de circuitos
de lectura para sensores MEMS capacitivos basados en codificación
temporal, y el diseño e implementación de conversores de datos
compactos para aplicaciones de audio basados en osciladores.
En el primer caso, el objetivo es la integración de un sensor MEMS
en un oscilador, haciendo que la frecuencia de oscilación depe capacidad del sensor. De esta forma, el sonido puede ser digitalizado
midiendo la frecuencia de oscilación, lo cual puede realizarse usando circuitos
en su mayor parte digitales. Sin embargo, un micrófono MEMS es
una estructura compleja en la que múltiples efectos parasÃticos pueden
alterar el correcto funcionamiento del oscilador. Este trabajo presenta
un análisis de la viabilidad de integrar un micrófono MEMS en diferentes
topologÃas de oscilador. La conclusión de este estudio es que los parasÃticos
del MEMS limitan el rendimiento del micrófono, causando que esta
solución no sea eficiente. En cambio, la implementación de conversores
analógico-digitales basados en codificación en frecuencia ha demostrado
ser una alternativa muy eficiente, lo cual motiva el estudio del siguiente
problema.
La segunda cuestión está centrada en el desarrollo de moduladores Sigma-Delta de alto orden basados en osciladores. En primer lugar se ha estudiado
la equivalencia entre los integradores clásicos y los integradores
referidos a la fase, seguido de una descripción de los conversores basados
en osciladores publicados en los últimos años. A continuación se
presenta un procedimiento para reemplazar integradores clásicos por integradores
referidos a la fase, incluyendo un ejemplo de diseño de un
modulador Sigma-Delta de segundo orden basado en osciladores. Posteriormente
se describen los principales problemas que limitan el rendimiento de este
tipo de sistemas, como el ruido de fase, el jitter o la metaestabilidad.
Esta tesis también presenta un nuevo método para evaluar el impacto
del ruido de fase y de la distorsión en sistemas basados en osciladores. El
método propuesto está basado en simulaciones PSS, las cuales permiten
la rápida estimación del rango dinámico del sistema sin necesidad de
recurrir a simulaciones temporales. Además, este trabajo describe una
nueva técnica para analizar el impacto del jitter de reloj en moduladores Sigma-Delta.
En esta tesis se han implementado dos circuitos integrados en tecnologÃa
CMOS de 0.13 μm, con el fin de demostrar la viabilidad de los
moduladores Sigma-Delta de alto orden basados en osciladores. Ambos chips han
sido diseñados para producir conformación espectral de ruido de segundo
orden, usando únicamente osciladores y circuitos mayoritariamente digitales.
El primer chip ha mostrado un error en el funcionamiento de los
circuitos digitales debido a la complejidad de las estructuras multi-bit
utilizadas. El segundo chip, implementado usando contadores de un solo
bit con el fin de simplificar el sistema, consigue conformación espectral
de ruido de segundo orden y alcanza 103 dB-A de rango dinámico en el
ancho de banda del audio, ocupando solo 0.04 mm2.Programa Oficial de Doctorado en IngenierÃa Eléctrica, Electrónica y AutomáticaPresidente: Georges G.E. Gielen.- Secretario: José Manuel de la Rosa.- Vocal: Ana Rus