140 research outputs found
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
Design, analysis and evaluation of sigma-delta based beamformers for medical ultrasound imaging applications
The inherent analogue nature of medical ultrasound signals in conjunction with the abundant merits provided by digital image acquisition, together with the increasing use of relatively simple front-end circuitries, have created considerable demand for single-bit beamformers in digital ultrasound imaging systems. Furthermore, the increasing need to design lightweight ultrasound systems with low power consumption and low noise, provide ample justification for development and innovation in the use of single-bit beamformers in ultrasound imaging systems. The overall aim of this research program is to investigate, establish, develop and confirm through a combination of theoretical analysis and detailed simulations, that utilize raw phantom data sets, suitable techniques for the design of simple-to-implement hardware efficient digital ultrasound beamformers to address the requirements for 3D scanners with large channel counts, as well as portable and lightweight ultrasound scanners for point-of-care applications and intravascular imaging systems.
In addition, the stability boundaries of higher-order High-Pass (HP) and Band-Pass (BP) Σ−Δ modulators for single- and dual- sinusoidal inputs are determined using quasi-linear modeling together with the describing-function method, to more accurately model the modulator quantizer. The theoretical results are shown to be in good agreement with the simulation results for a variety of input amplitudes, bandwidths, and modulator orders. The proposed mathematical models of the quantizer will immensely help speed up the design of higher order HP and BP Σ−Δ modulators to be applicable for digital ultrasound beamformers.
Finally, a user friendly design and performance evaluation tool for LP, BP and HP modulators is developed. This toolbox, which uses various design methodologies and covers an assortment of modulators topologies, is intended to accelerate the design process and evaluation of modulators. This design tool is further developed to enable the design, analysis and evaluation of beamformer structures including the noise analyses of the final B-scan images. Thus, this tool will allow researchers and practitioners to design and verify different reconstruction filters and analyze the results directly on the B-scan ultrasound images thereby saving considerable time and effort
Oversampled analog-to-digital converter architectures based on pulse frequency modulation
Mención Internacional en el título de doctorThe purpose of this research work is providing new insights in the development
of voltage-controlled oscillator based analog-to-digital converters (VCO-based
ADCs). Time-encoding based ADCs have become of great interest to the designer
community due to the possibility of implementing mostly digital circuits,
which are well suited for current deep-submicron CMOS processes. Within this
topic, VCO-based ADCs are one of the most promising candidates.
VCO-based ADCs have typically been analyzed considering the output phase
of the oscillator as a state variable, similar to the state variables considered in __
modulation loops. Although this assumption might take us to functional designs
(as verified by literature), it does not take into account neither the oscillation
parameters of the VCO nor the deterministic nature of quantization noise. To
overcome this issue, we propose an interpretation of these type of systems based
on the pulse frequency modulation (PFM) theory. This permits us to analytically
calculate the quantization noise, in terms of the working parameters of the system.
We also propose a linear model that applies to VCO-based systems. Thanks to
it, we can determine the different error processes involved in the digitization of
the input data, and the performance limitations which these processes direct to.
A generic model for any order open-loop VCO-based ADCs is made based on the
PFM theory. However, we will see that only the first-order case and a second order
approximation can be implemented in practice. The PFM theory also
allows us to propose novel approaches to both single-stage and multistage VCObased
architectures. We describe open-loop architectures such as VCO-based
architectures with digital precoding, PFM-based architectures that can be used
as efficient ADCs or MASH architectures with optimal noise-transfer-function
(NTF) zeros. We also make a first approach to the proposal and analysis of closed loop
architectures. At the same time, we deal with one of the main limitations of
VCOs (especially those built with ring oscillators), which is the non-linear voltage to-
frequency relation. In this document, we describe two techniques mitigate this
phenomenon.
Firstly, we propose to use a pulse width modulator in front of the VCO. This
way, there are only two possible oscillation states. Consequently, the oscillator
works linearly. To validate the proposed technique, an experimental prototype
was implemented in a 40-nm CMOS process. The chip showed noise problems
that degraded the expected resolution, but allowed us to verify that the potential
performance was close to the expected one. A potential signal-to-noise-distortion
ratio (SNDR) equal to 56 dB was achieved in 20 MHz bandwidth, consuming
2.15 mW with an occupied area equal to 0.03 mm2. In comparison to other equivalent systems, the proposed architecture is simpler, while keeping similar
power consumption and linearity properties.
Secondly, we used a pulse frequency modulator to implement a second ADC.
The proposed architecture is intrinsically linear and uses a digital delay line to
increase the resolution of the converter. One experimental prototype was implemented
in a 40-nm CMOS process using one of these architectures. Proper results
were measured from this prototype. These results allowed us to verify that the
PFM-based architecture could be used as an efficient ADC. The measured peak
SNDR was equal to 53 dB in 20 MHz bandwidth, consuming 3.5 mW with an
occupied area equal to 0.08 mm2. The architecture shows a great linearity, and
in comparison to related work, it consumes less power and occupies similar area.
In general, the theoretical analyses and the architectures proposed in the
document are not restricted to any application. Nevertheless, in the case of the
experimental chips, the specifications required for these converters were linked to
communication applications (e.g. VDSL, VDSL2, or even G.fast), which means
medium resolution (9-10 bits), high bandwidth (20 MHz), low power and low
area.El propósito del trabajo presentado en este documento es aportar una nueva perspectiva
para el diseño de convertidores analógico-digitales basados en osciladores
controlados por tensión. Los convertidores analógico-digitales con codificación
temporal han llamado la atención durante los últimos años de la comunidad de
diseñadores debido a la posibilidad de implementarlos en su gran mayoría con
circuitos digitales, los cuales son muy apropiados para los procesos de diseño
manométricos. En este ámbito, los convertidores analógico-digitales basados en
osciladores controlados por tensión son uno de los candidatos más prometedores.
Los convertidores analógico-digitales basados en osciladores controlados por
tensión han sido típicamente analizados considerando que la fase del oscilador
es una variable de estado similar a las que se observan en los moduladores __.
Aunque esta consideración puede llevarnos a diseños funcionales (como se puede
apreciar en muchos artículos de la literatura), en ella no se tiene en cuenta ni
los parámetros de oscilación ni la naturaleza determinística del ruido de cuantificación. Para solventar esta cuestión, en este documento se propone una interpretación alternativa de este tipo de sistemas haciendo uso de la teoría de
la modulación por frecuencia de pulsos. Esto nos permite calcular de forma
analítica las ecuaciones que modelan el ruido de cuantificación en función de los
parámetros de oscilación. Se propone también un modelo lineal para el análisis de
convertidores analógico-digitales basados en osciladores controlados por tensión.
Este modelo permite determinar las diferentes fuentes de error que se producen
durante el proceso de digitalización de los datos de entrada y las limitaciones
que suponen. Un modelo genérico de convertidor de cualquier orden se propone
con la ayuda de este modelo. Sin embargo, solo los casos de primer orden y una
aproximación al caso de segundo orden se pueden implementar en la práctica.
La teoría de la modulación por frecuencia de pulsos también permite nuevas perspectivas
para la propuesta y el análisis tanto de arquitecturas de una sola etapa
como de arquitecturas de varias etapas construidas con osciladores controlados
por tensión. Se proponen y se describen arquitecturas en lazo abierto como son
las basadas en osciladores controlador por tensión con moduladores digitales en
la etapa de entrada, moduladores por frecuencia de pulsos que se utilizan como
convertidores analógico-digitales eficientes o arquitecturas en cascada en las que
se optimizan la distribución de los ceros en la función de transferencia del ruido.
También se realiza una aproximación a la propuesta y el análisis de arquitecturas
en lazo cerrado. Al mismo tiempo, se aborda una de las problemáticas más importantes
de los osciladores controlados por tensión (especialmente en aquellos
implementados mediante osciladores en anillo): la relación tensión-freculineal que presentan este tipo de circuitos. En el documento, se describen dos
técnicas cuyo objetivo es mitigar esta limitación.
La primera técnica de corrección se basa en el uso de un modulador por
ancho de pulsos antes del oscilador controlado por tensión. De esta forma, solo
existen dos estados de oscilación en el oscilador, se trabaja de forma lineal y
no se genera distorsión en los datos de salida. La técnica se propone de forma
teórica haciendo uso de la teoría desarrollada previamente. Para llevar a cabo
la validación de la propuesta teórica se fabricó un prototipo experimental en un
proceso CMOS de 40-nm. El chip mostró problemas de ruido que limitaban la
resolución, sin embargo, nos permitió velicar que la resolución ideal que se podrá
haber obtenido estaba muy cercana a la resolución esperada. Se obtuvo una
potencial relación señal-(ruido-distorsión) igual a 56 dB en 20 MHz de ancho de
banda, un consumo de 2.15 mW y un área igual a 0.03 mm2. En comparación con
sistemas equivalentes, la arquitectura propuesta es más simple al mismo tiempo
que se mantiene el consumo así como la linealidad.
A continuación, se propone la implementación de un convertidor analógico digital
mediante un modulador por frecuencia de pulsos. La arquitectura propuesta
es intrínsecamente lineal y hace uso de una línea de retraso digital con
el fin de mejorar la resolución del convertidor. Como parte del trabajo experimental,
se fabricó otro chip en tecnología CMOS de 40 nm con dicha arquitectura,
de la que se obtuvieron resultados notables. Estos resultados permitieron
verificar que la arquitectura propuesta, en efecto, podrá emplearse como convertidor
analógico-digital eficiente. La arquitectura consigue una relación real
señal-(ruido-distorsión) igual a 53 dB en 20 MHz de ancho de banda, un consumo
de 3.5 mW y un área igual a 0.08 mm2. Se obtiene una gran linealidad y, en
comparación con arquitecturas equivalentes, el consumo es menor mientras que
el área ocupada se mantiene similar.
En general, las aportaciones propuestas en este documento se pueden aplicar a
cualquier tipo de aplicación, independientemente de los requisitos de resolución,
ancho de banda, consumo u área. Sin embargo, en el caso de los prototipos
fabricados, las especificaciones se relacionan con el ámbito de las comunicaciones
(VDSL, VDSL2, o incluso G.fast), en donde se requiere una resolución media
(9-10 bits), alto ancho de banda (20 MHz), manteniendo bajo consumo y baja
área ocupada.Programa Oficial de Doctorado en Ingeniería Eléctrica, Electrónica y AutomáticaPresidente: Michael Peter Kennedy.- Secretario: Antonio Jesús López Martín.- Vocal: Jörg Hauptman
Analysis, simulation and design of nonlinear RF circuits
The PhD project consists of two parts. The first part concerns the development of Computer Aided Design (CAD) algorithms for high-frequency circuits. Novel Padébased
algorithms for numerical integration of ODEs as arise in high-frequency circuits are proposed. Both single- and multi-step methods are introduced. A large part of this
section of the research is concerned with the application of Filon-type integration techniques to circuits subject to modulated signals. Such methods are tested with analog
and digital modulated signals and are seen to be very effective. The results confirm that these methods are more accurate than the traditional trapezoidal rule and Runge-Kutta methods.
The second part of the research is concerned with the analysis, simulation and design of RF circuits with emphasis on injection-locked frequency dividers (ILFD)
and digital delta-sigma modulators (DDSM). Both of these circuits are employed in fractional-N frequency synthesizers. Several simulation methods are proposed to capture the locking range of an ILFD, such as the Warped Multi-time Partial Differential Equation (WaMPDE) and the Multiple-Phase-Condition Envelope Following (MPCENV)
methods. The MPCENV method is the more efficient and accurate simulation technique and it is recommended to obviate the need for expensive experiments. The
Multi-stAge noise Shaping (MASH) digital delta-sigma modulator (DDSM) is simulated in MATLAB and analysed mathematically. A novel structure employing multimoduli,
termed the MM-MASH, is proposed. The goal in this design work is to reduce the noise level in the useful frequency band of the modulator. The success of the novel
structure in achieving this aim is confirmed with simulations
Design and Implementation of Novel FPGA Based Time-Interleaved Variable Centre-Frequency Digital Sigma-Delta Modulators
Novel, multi-path, time-interleaved digital sigma-delta modulators that can operate at any arbitrary frequency from DC to Nyquist are designed, analysed and synthesized in this study. Dual- and quadruple-path fourth-order Butterworth, Chebyshev, Inverse Chebyshev and Elliptical based digital sigma-delta modulators, which offer designers the flexibility of specifying the centre-frequency, pass-band/stop-band attenuation as well as the signal bandwidth are presented. These topologies are compared in terms of their signal-to-noise ratios, hardware complexity, stability, tonality and sensitivity to non-idealities. Detailed simulations performed at the behavioural-level in MATLAB are compared with the experimental results of the FPGA implementation of the designed modulators. The signal-to-noise ratios between the simulated and empirical results are shown to be different by not more than 3-5 dBs. Furthermore, this paper presents the mathematical modelling and evaluation of the tones caused by the finite wordlengths of these digital multi-path sigma-delta modulators when excited by sinusoidal input signals
Digital Compensation for MASH Sigma Delta Modulators using H-infinity Approach
[[abstract]]This paper presents a new digital compensation scheme for MASH (cascaded) sigma-delta modulators (SigmaDeltaMs) with 1-bit quantizer. The compensation scheme is designed based on the well-known internal model principle and H-infinity control theory. For numerical illustration, we concentrate on a MASH 2-1 SigmaDeltaM architecture for low and middle frequencies applications. Comparisons between the proposed SigmaDeltaM and the conventional one are made, which reveal that the proposed SigmaDeltaM outperforms the conventional one in several aspects - signal-to-noise ratio (SNR), dynamic range (DR), output swing.[[conferencetype]]åé[[conferencedate]]20081012~20081015[[iscallforpapers]]Y[[conferencelocation]]Singapor
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