171 research outputs found
A New Technique for the Design of Multi-Phase Voltage Controlled Oscillators
© 2017 World Scientific Publishing Company.In this work, a novel circuit structure for second-harmonic multi-phase voltage controlled oscillator (MVCO) is presented. The proposed MVCO is composed of (Formula presented.) ((Formula presented.) being an integer number and (Formula presented.)2) identical inductor–capacitor ((Formula presented.)) tank VCOs. In theory, this MVCO can provide 2(Formula presented.) different phase sinusoidal signals. A six-phase VCO based on the proposed structure is designed in a TSMC 0.18(Formula presented.)um CMOS process. Simulation results show that at the supply voltage of 0.8(Formula presented.)V, the total power consumption of the six-phase VCO circuit is about 1(Formula presented.)mW, the oscillation frequency is tunable from 2.3(Formula presented.)GHz to 2.5(Formula presented.)GHz when the control voltage varies from 0(Formula presented.)V to 0.8(Formula presented.)V, and the phase noise is lower than (Formula presented.)128(Formula presented.)dBc/Hz at 1(Formula presented.)MHz offset frequency. The proposed MVCO has lower phase noise, lower power consumption and more outputs than other related works in the literature.Peer reviewedFinal Accepted Versio
Analysis and design of wideband voltage controlled oscillators using self-oscillating active inductors.
Voltage controlled oscillators (VCOs) are essential components of RF circuits used in
transmitters and receivers as sources of carrier waves with variable frequencies. This, together
with a rapid development of microelectronic circuits, led to an extensive research
on integrated implementations of the oscillator circuits. One of the known approaches
to oscillator design employs resonators with active inductors electronic circuits simulating
the behavior of passive inductors using only transistors and capacitors. Such
resonators occupy only a fraction of the silicon area necessary for a passive inductor,
and thus allow to use chip area more eectively. The downsides of the active inductor
approach include: power consumption and noise introduced by transistors.
This thesis presents a new approach to active inductor oscillator design using selfoscillating
active inductor circuits. The instability necessary to start oscillations is
provided by the use of a passive RC network rather than a power consuming external
circuit employed in the standard oscillator approach. As a result, total power consumption
of the oscillator is improved. Although, some of the active inductors with
RC circuits has been reported in the literature, there has been no attempt to utilise
this technique in wideband voltage controlled oscillator design. For this reason, the
dissertation presents a thorough investigation of self-oscillating active inductor circuits,
providing a new set of design rules and related trade-os. This includes: a complete
small signal model of the oscillator, sensitivity analysis, large signal behavior of the circuit
and phase noise model. The presented theory is conrmed by extensive simulations
of wideband CMOS VCO circuit for various temperatures and process variations. The obtained results prove that active inductor oscillator performance is obtained without
the use of standard active compensation circuits. Finally, the concept of self-oscillating
active inductor has been employed to simple and fast OOK (On-Off Keying) transmitter
showing energy eciency comparable to the state of the art implementations reported
in the literature
Design considerations for integrated continuous-time chaotic oscillators
This paper presents an optimization procedure to choose the chaotic state equation which is best suited for implementation using Gm-C integrated circuit techniques. The paper also presents an analysis of the most significant hardware nonidealities of Gm-C circuits on the chaotic operation-the basis to design robust integrated circuits with reproducible and easily controllable behavior. The techniques in the paper are illustrated through a circuit fabricated in 2.4-/iin double-poly technology.Comisión Interministerial de Ciencia y Tecnología TIC 96-1392-CO2-
High-Bandwidth Voltage-Controlled Oscillator based architectures for Analog-to-Digital Conversion
The purpose of this thesis is the proposal and implementation of data conversion
open-loop architectures based on voltage-controlled oscillators (VCOs) built with
ring oscillators (RO-based ADCs), suitable for highly digital designs, scalable to
the newest complementary metal-oxide-semiconductor (CMOS) nodes.
The scaling of the design technologies into the nanometer range imposes the
reduction of the supply voltage towards small and power-efficient architectures,
leading to lower voltage overhead of the transistors. Additionally, phenomena
like a lower intrinsic gain, inherent noise, and parasitic effects (mismatch between
devices and PVT variations) make the design of classic structures for ADCs more
challenging. In recent years, time-encoded A/D conversion has gained relevant
popularity due to the possibility of being implemented with mostly digital structures.
Within this trend, VCOs designed with ring oscillator based topologies
have emerged as promising candidates for the conception of new digitization
techniques.
RO-based data converters show excellent scalability and sensitivity, apart from
some other desirable properties, such as inherent quantization noise shaping and
implicit anti-aliasing filtering. However, their nonlinearity and the limited time
delay achievable in a simple NOT gate drastically limits the resolution of the converter,
especially if we focus on wide-band A/D conversion. This thesis proposes
new ways to alleviate these issues.
Firstly, circuit-based techniques to compensate for the nonlinearity of the ring
oscillator are proposed and compared to equivalent state-of-the-art solutions.
The proposals are designed and simulated in a 65-nm CMOS node for open-loop
RO-based ADC architectures. One of the techniques is also validated experimentally
through a prototype. Secondly, new ways to artificially increase the effective
oscillation frequency are introduced and validated by simulations. Finally, new
approaches to shape the quantization noise and filter the output spectrum of a
RO-based ADC are proposed theoretically. In particular, a quadrature RO-based
band-pass ADC and a power-efficient Nyquist A/D converter are proposed and
validated by simulations.
All the techniques proposed in this work are especially devoted for highbandwidth
applications, such as Internet-of-Things (IoT) nodes or maximally
digital radio receivers. Nevertheless, their field of application is not restricted to
them, and could be extended to others like biomedical instrumentation or sensing.El propósito de esta tesis doctoral es la propuesta y la implementación de arquitecturas
de conversión de datos basadas en osciladores en anillos, compatibles
con diseños mayoritariamente digitales, escalables en los procesos CMOS de fabricación
más modernos donde las estructuras digitales se ven favorecidas.
La miniaturización de las tecnologías CMOS de diseño lleva consigo la reducción
de la tensión de alimentación para el desarrollo de arquitecturas pequeñas
y eficientes en potencia. Esto reduce significativamente la disponibilidad de tensión
para saturar transistores, lo que añadido a una ganancia cada vez menor
de los mismos, ruido y efectos parásitos como el “mismatch” y las variaciones
de proceso, tensión y temperatura han llevado a que sea cada vez más complejo
el diseño de estructuras analógicas eficientes. Durante los últimos años la conversión
A/D basada en codificación temporal ha ganado gran popularidad dado
que permite la implementación de estructuras mayoritariamente digitales. Como
parte de esta evolución, los osciladores controlados por tensión diseñados con topologías
de oscilador en anillo han surgido como un candidato prometedor para
la concepción de nuevas técnicas de digitalización.
Los convertidores de datos basados en osciladores en anillo son extremadamente
sensibles (variación de frecuencia con respecto a la señal de entrada) así como
escalables, además de otras propiedades muy atractivas, como el conformado
espectral de ruido de cuantificación y el filtrado “anti-aliasing”. Sin embargo, su
respuesta no lineal y el limitado tiempo de retraso alcanzable por una compuerta
NOT restringen la resolución del conversor, especialmente para conversión A/D
en aplicaciones de elevado ancho de banda. Esta tesis doctoral propone nuevas
técnicas para aliviar este tipo de problemas.
En primer lugar, se proponen técnicas basadas en circuito para compensar el
efecto de la no linealidad en los osciladores en anillo, y se comparan con soluciones
equivalentes ya publicadas. Las propuestas se diseñan y simulan en tecnología
CMOS de 65 nm para arquitecturas en lazo abierto. Una de estas técnicas
presentadas es también validada experimentalmente a través de un prototipo.
En segundo lugar, se introducen y validan por simulación varias formas de incrementar
artificialmente la frecuencia de oscilación efectiva. Para finalizar, se
proponen teóricamente dos enfoques para configurar nuevas formas de conformación
del ruido de cuantificación y filtrado del espectro de salida de los datos
digitales. En particular, son propuestos y validados por simulación un ADC pasobanda
en cuadratura de fase y un ADC de Nyquist de gran eficiencia en potencia. Todas las técnicas propuestas en este trabajo están destinadas especialmente
para aplicaciones de alto ancho de banda, tales como módulos para el Internet
de las cosas o receptores de radiofrecuencia mayoritariamente digitales. A pesar
de ello, son extrapolables también a otros campos como el de la instrumentación
biomédica o el de la medición de señales mediante sensores.Programa de Doctorado en Ingeniería Eléctrica, Electrónica y Automática por la Universidad Carlos III de MadridPresidente: Juan Pablo Alegre Pérez.- Secretario: Celia López Ongil.- Vocal: Fernando Cardes Garcí
A wideband linear tunable CDTA and its application in field programmable analogue array
This document is the Accepted Manuscript version of the following article: Hu, Z., Wang, C., Sun, J. et al. ‘A wideband linear tunable CDTA and its application in field programmable analogue array’, Analog Integrated Circuits and Signal Processing, Vol. 88 (3): 465-483, September 2016. Under embargo. Embargo end date: 6 June 2017. The final publication is available at Springer via https://link.springer.com/article/10.1007%2Fs10470-016-0772-7 © Springer Science+Business Media New York 2016In this paper, a NMOS-based wideband low power and linear tunable transconductance current differencing transconductance amplifier (CDTA) is presented. Based on the NMOS CDTA, a novel simple and easily reconfigurable configurable analogue block (CAB) is designed. Moreover, using the novel CAB, a simple and versatile butterfly-shaped FPAA structure is introduced. The FPAA consists of six identical CABs, and it could realize six order current-mode low pass filter, second order current-mode universal filter, current-mode quadrature oscillator, current-mode multi-phase oscillator and current-mode multiplier for analog signal processing. The Cadence IC Design Tools 5.1.41 post-layout simulation and measurement results are included to confirm the theory.Peer reviewedFinal Accepted Versio
CMOS design of chaotic oscillators using state variables: a monolithic Chua's circuit
This paper presents design considerations for monolithic implementation of piecewise-linear (PWL) dynamic systems in CMOS technology. Starting from a review of available CMOS circuit primitives and their respective merits and drawbacks, the paper proposes a synthesis approach for PWL dynamic systems, based on state-variable methods, and identifies the associated analog operators. The GmC approach, combining quasi-linear VCCS's, PWL VCCS's, and capacitors is then explored regarding the implementation of these operators. CMOS basic building blocks for the realization of the quasi-linear VCCS's and PWL VCCS's are presented and applied to design a Chua's circuit IC. The influence of GmC parasitics on the performance of dynamic PWL systems is illustrated through this example. Measured chaotic attractors from a Chua's circuit prototype are given. The prototype has been fabricated in a 2.4- mu m double-poly n-well CMOS technology, and occupies 0.35 mm/sup 2/, with a power consumption of 1.6 mW for a +or-2.5-V symmetric supply. Measurements show bifurcation toward a double-scroll Chua's attractor by changing a bias current
Systematic Comparison of HF CMOS Transconductors
Transconductors are commonly used as active elements in high-frequency (HF) filters, amplifiers, mixers, and oscillators. This paper reviews transconductor design by focusing on the V-I kernel that determines the key transconductor properties. Based on bandwidth considerations, simple V-I kernels with few or no internal nodes are preferred. In a systematic way, virtually all simple kernels published in literature are generated. This is done in two steps: 1) basic 3-terminal transconductors are covered and 2) then five different techniques to combine two of them in a composite V-I kernel. In order to compare transconductors in a fair way, a normalized signal-to-noise ratio (NSNR) is defined. The basic V-I kernels and the five classes of composite V-I kernels are then compared, leading to insight in the key mechanisms that affect NSNR. Symbolic equations are derived to estimate NSNR, while simulations with more advanced MOSFET models verify the results. The results show a strong tradeoff between NSNR and transconductance tuning range. Resistively generated MOSFETs render the best NSNR results and are robust for future technology developments
Analysis and design of oscillators based on low-voltage self-oscillating active inductors
This paper presents a new consistent analysis of self-oscillating active in-
ductors together with a complete design example of a 90 nm CMOS current controlled
oscillator (CCO) for ISMapplications. Using the proposed passive compensation method
in place of a standard negative impedance converter, typical performance of active induc-
tor oscillator is achieved with reduced static power consumption. The article presents
a small signal, large signal and phase noise analysis of the proposed oscillator together
with related design trade-offs. Theoretical results are confirmed by a simulation of cur-
rent controlled oscillator designed using UMC 90 nm 1P9M RF process libraries. The
proposed circuit achieves a relative tuning range of 26% with a 434 MHz carrier fre-
quency and average in band phase noise of -92 dBc/Hz at 1 MHz offset. The maximum
power consumption of the oscillator core is only 2 mW from a 1 V supply
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