18 research outputs found
A 0.18μm CMOS 9mW current-mode FLF linear phase filter with gain boost
“This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. In most cases, these works may not be reposted without the explicit permission of the copyright holder." “Copyright IEEE. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE.”The design and implementation of a CMOS continuous-time follow-the-leader-feedback (FLF) filter is described. The filter is implemented using a fully-differential linear, low voltage and low power consumption operational transconductance amplifier (OTA) based on a source degeneration topology. PSpice simulations using a standard TSMC 0.18 mum CMOS process with 2 V power supply have shown that the cut-off frequency of the filter ranges from 55 MHz to 160 MHz and dynamic range is about 45 dB. The group delay is less than 5% over the whole tuning range; the power consumption is only 9 mW
A CMOS 100 MHz continuous-time seventh order 0.05° equiripple linear phase leapfrog multiple loop feedback Gm-C filter
“This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. In most cases, these works may not be reposted without the explicit permission of the copyright holder." “Copyright IEEE. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE.”A novel 100 MHz CMOS Gm-C seventh-order 0.05° equiripple linear phase low-pass multiple loop feedback (MLF) filter based on leapfrog (LF) topology is presented. The filter is implemented using a fully-differential linear, high performance operational transconductance amplifier (OTA) based on cross-coupled pairs. PSpice simulations in a standard TSMC 0.25 μm CMOS process and with a single 5 V power supply have shown that the cut-off frequency of the filter without and with gain boost ranges from 8-32 MHz and 15-100 MHz, respectively. With gain boost, total harmonic distortion (THD) for a differential input voltage Vid of 315 mVpp at 1 MHz is less than -40 dB, dynamic range at 1% THD is over 55 dB, output noise with bandwidth 500 MHz is only 300 μVRMS, and power consumption is 322 mW
Design of adaptive analog filters for magnetic front-end read channels
Esta tese estuda o projecto e o comportamento de filtros em tempo contínuo de
muito-alta-frequência. A motivação deste trabalho foi a investigação de soluções de filtragem
para canais de leitura em sistemas de gravação e reprodução de dados em suporte
magnético, com custos e consumo (tamanho total inferior a 1 mm2 e consumo inferior a
1mW/polo), inferiores aos circuitos existentes. Nesse sentido, tal como foi feito neste
trabalho, o rápido desenvolvimento das tecnologias de microelectrónica suscitou esforços
muito significativos a nível mundial com o objectivo de se investigarem novas técnicas
de realização de filtros em circuito integrado monolítico, especialmente em tecnologia
CMOS (Complementary Metal Oxide Semiconductor). Apresenta-se um estudo comparativo
a diversos níveis hierárquicos do projecto, que conduziu à realização e caracterização
de soluções com as características desejadas.
Num primeiro nível, este estudo aborda a questão conceptual da gravação e transmissão
de sinal bem como a escolha de bons modelos matemáticos para o tratamento da
informação e a minimização de erro inerente às aproximações na conformidade aos princípios
físicos dos dispositivos caracterizados.
O trabalho principal da tese é focado nos níveis hierárquicos da arquitectura do
canal de leitura e da realização em circuito integrado do seu bloco principal – o bloco de
filtragem. Ao nível da arquitectura do canal de leitura, apresenta-se um estudo alargado
sobre as metodologias existentes de adaptação de sinal e recuperação de dados em suporte
magnético. Este desígnio aparece no âmbito da proposta de uma solução de baixo custo,
baixo consumo, baixa tensão de alimentação e baixa complexidade, alicerçada em tecnologia
digital CMOS, para a realização de um sistema DFE (Decision Feedback Equalization)
com base na igualização de sinal utilizando filtros integrados analógicos em tempo
contínuo.
Ao nível do projecto de realização do bloco de filtragem e das técnicas de implementação
de filtros e dos seus blocos constituintes em circuito integrado, concluiu-se que
a técnica baseada em circuitos de transcondutância e condensadores, também conhecida como filtros gm-C (ou transcondutância-C), é a mais adequada para a realização de filtros
adaptativos em muito-alta-frequência. Definiram-se neste nível hierárquico mais baixo,
dois subníveis de aprofundamento do estudo no âmbito desta tese, nomeadamente: a pesquisa
e análise de estruturas ideais no projecto de filtros recorrendo a representações no
espaço de estados; e, o estudo de técnicas de realização em tecnologia digital CMOS de
circuitos de transcondutância para a implementação de filtros integrados analógicos em
tempo contínuo.
Na sequência deste estudo, apresentam-se e comparam-se duas estruturas de filtros
no espaço de estados, correspondentes a duas soluções alternativas para a realização de
um igualador adaptativo realizado por um filtro contínuo passa-tudo de terceira ordem,
para utilização num canal de leitura de dados em suporte magnético.
Como parte constituinte destes filtros, apresenta-se uma técnica de realização de
circuitos de transcondutância, e de realização de condensadores lineares usando matrizes
de transístores MOSFET para processamento de sinal em muito-alta-frequência realizada
em circuito integrado usando tecnologia digital CMOS submicrométrica. Apresentam-se
métodos de adaptação automática capazes de compensar os erros face aos valores nominais
dos componentes, devidos às tolerâncias inerentes ao processo de fabrico, para os
quais apresentamos os resultados de simulação e de medição experimental obtidos.
Na sequência deste estudo, resultou igualmente a apresentação de um circuito passível
de constituir uma solução para o controlo de posicionamento da cabeça de leitura
em sistemas de gravação/reprodução de dados em suporte magnético. O bloco proposto
é um filtro adaptativo de primeira ordem, com base nos mesmos circuitos de transcondutância
e técnicas de igualação propostos e utilizados na implementação do filtro adaptativo
de igualação do canal de leitura.
Este bloco de filtragem foi projectado e incluído num circuito integrado (Jaguar) de
controlo de posicionamento da cabeça de leitura realizado para a empresa ATMEL em
Colorado Springs, e incluído num produto comercial em parceria com uma empresa escocesa
utilizado em discos rígidos amovíveis.This thesis studies the design and behavior of continuous-time very-high-frequency
filters. The motivation of this work was the search for filtering solutions for the readchannel
in recording and reproduction of data on magnetic media systems, with costs and
consumption (total size less than 1 mm2 and consumption under 1mW/pole), lower than
the available circuits. Accordingly, as was done in this work, the rapid development of
microelectronics technology raised very significant efforts worldwide in order to investigate
new techniques for implementing such filters in monolithic integrated circuit, especially
in CMOS technology (Complementary Metal Oxide Semiconductor). We present
a comparative study on different hierarchical levels of the project, which led to the realization
and characterization of solutions with the desired characteristics.
In the first level, this study addresses the conceptual question of recording and
transmission of signal and the choice of good mathematical models for the processing of
information and minimization of error inherent in the approaches and in accordance with
the principles of the characterized physical devices.
The main work of this thesis is focused on the hierarchical levels of the architecture
of the read channel and the integrated circuit implementation of its main block - the filtering
block. At the architecture level of the read channel this work presents a comprehensive
study on existing methodologies of adaptation and signal recovery of data on
magnetic media. This project appears in the sequence of the proposed solution for a lowcost,
low consumption, low voltage, low complexity, using CMOS digital technology for
the performance of a DFE (Decision Feedback Equalization) based on the equalization of
the signal using integrated analog filters in continuous time.
At the project level of implementation of the filtering block and techniques for implementing
filters and its building components, it was concluded that the technique based
on transconductance circuits and capacitors, also known as gm-C filters is the most appropriate
for the implementation of very-high-frequency adaptive filters. We defined in
this lower level, two sub-levels of depth study for this thesis, namely: research and analysis
of optimal structures for the design of state-space filters, and the study of techniques for the design of transconductance cells in digital CMOS circuits for the implementation
of continuous time integrated analog filters.
Following this study, we present and compare two filtering structures operating in
the space of states, corresponding to two alternatives for achieving a realization of an
adaptive equalizer by the use of a continuous-time third order allpass filter, as part of a
read-channel for magnetic media devices.
As a constituent part of these filters, we present a technique for the realization of
transconductance circuits and for the implementation of linear capacitors using arrays of
MOSFET transistors for signal processing in very-high-frequency integrated circuits using
sub-micrometric CMOS technology. We present methods capable of automatic adjustment
and compensation for deviation errors in respect to the nominal values of the
components inherent to the tolerances of the fabrication process, for which we present
the simulation and experimental measurement results obtained.
Also as a result of this study, is the presentation of a circuit that provides a solution
for the control of the head positioning on recording/playback systems of data on magnetic
media. The proposed block is an adaptive first-order filter, based on the same transconductance
circuits and equalization techniques proposed and used in the implementation
of the adaptive filter for the equalization of the read channel.
This filter was designed and included in an integrated circuit (Jaguar) used to control
the positioning of the read-head done for ATMEL company in Colorado Springs, and
part of a commercial product used in removable hard drives fabricated in partnership with a Scottish company
A 0.18μm CMOS 300MHz Current-Mode LF Seventh-order Linear Phase Filter for Hard Disk Read Channels
“This material is presented to ensure timely dissemination of scholarly and technical work. Copyright and all rights therein are retained by authors or by other copyright holders. All persons copying this information are expected to adhere to the terms and constraints invoked by each author's copyright. In most cases, these works may not be reposted without the explicit permission of the copyright holder." “Copyright IEEE. Personal use of this material is permitted. However, permission to reprint/republish this material for advertising or promotional purposes or for creating new collective works for resale or redistribution to servers or lists, or to reuse any copyrighted component of this work in other works must be obtained from the IEEE.”A 300MHz CMOS seventh-order linear phase gm-C filter based on a current-mode multiple loop feedback (MLF) leap-frog (LF) structure is realized. The filter is implemented using a fully-differential linear operational transconductance amplifier (OTA) based on a source degeneration topology. PSpice simulations using a standard TSMC 0.18μm CMOS process with 2.5V power supply have shown that the cut-off frequency of the filter can be tuned from 260MHz to 320MHz and dynamic range is about 66dB. Group delay ripple is approximately 4.5% over the whole tuning range and maximum power consumption is 210mW
Low-voltage tunable pseudo-differential transconductor with high linearity
A novel tunable transconductor is presented. Input
transistors operate in the triode region to achieve
programmable voltage-to-current conversion. These
transistors are kept in the triode region by a novel
negative feedback loop which features simplicity, low
voltage requirements, and high output resistance. A
linearity analysis is carried out which demonstrates how
the proposed transconductance tuning scheme leads to
high linearity in a wide transconductance range.
Measurement results for a 0.5 μm CMOS implementation
of the transconductor show a transconductance tuning
range of more than a decade (15 μA/V to 165 μA/V) and a
total harmonic distortion of −67 dB at 1 MHz for an input
of 1 Vpp and a supply voltage of 1.8 V
Nonlinearity and noise modeling of operational transconductance amplifiers for continuous time analog filters
A general framework for performance optimization of continuous-time OTA-C
(Operational Transconductance Amplifier-Capacitor) filters is proposed. Efficient
procedures for evaluating nonlinear distortion and noise valid for any filter of arbitrary
order are developed based on the matrix description of a general OTA-C filter model .
Since these procedures use OTA macromodels, they can be used to obtain the results
significantly faster than transistor-level simulation. In the case of transient analysis, the
speed-up may be as much as three orders of magnitude without almost no loss of
accuracy. This makes it possible to carry out direct numerical optimization of OTA-C
filters with respect to important characteristics such as noise performance, THD, IM3,
DR or SNR. On the other hand, the general OTA-C filter model allows us to apply
matrix transforms that manipulate (rescale) filter element values and/or change topology
without changing its transfer function. The above features are a basis to build automated
optimization procedures for OTA-C filters. In particular, a systematic optimization
procedure using equivalence transformations is proposed. The research also proposes
suitable software implementations of the optimization process. The first part of the
research proposes a general performance optimization procedure and to verify the
process two application type examples are mentioned. An application example of the
proposed approach to optimal block sequencing and gain distribution of 8th order
cascade Butterworth filter (for two variants of OTA topologies) is given. Secondly the
modeling tool is used to select the best suitable topology for a 5th order Bessel Low Pass
Filter. Theoretical results are verified by comparing to transistor-level simulation withCADENCE. For the purpose of verification, the filters have also been fabricated in
standard 0.5mm CMOS process.
The second part of the research proposes a new linearization technique to
improve the linearity of an OTA using an Active Error Feedforward technique. Most
present day applications require very high linear circuits combined with low noise and
low power consumption. An OTA based biquad filter has also been fabricated in 0.35mm
CMOS process. The measurement results for the filter and the stand alone OTA have
been discussed. The research focuses on these issues
Continuous-time low-pass filters for integrated wideband radio receivers
This thesis concentrates on the design and implementation of analog baseband continuous-time low-pass filters for integrated wideband radio receivers. A total of five experimental analog baseband low-pass filter circuits were designed and implemented as a part of five single-chip radio receivers in this work.
After the motivation for the research work presented in this thesis has been introduced, an overview of analog baseband filters in radio receivers is given first. In addition, a review of the three receiver architectures and the three wireless applications that are adopted in the experimental work of this thesis is presented. The relationship between the integrator non-idealities and integrator Q-factor, as well as the effect of the integrator Q-factor on the filter frequency response, are thoroughly studied on the basis of a literature review. The theoretical study that is provided is essential for the gm-C filter synthesis with non-ideal lossy integrators that is presented after the introduction of different techniques to realize integrator-based continuous-time low-pass filters. The filter design approach proposed for gm-C filters is original work and one of the main points in this thesis, in addition to the experimental IC implementations.
Two evolution versions of fourth-order 10-MHz opamp-RC low-pass filters designed and implemented for two multicarrier WCDMA base-station receivers in a 0.25-µm SiGe BiCMOS technology are presented, along with the experimental results of both the low-pass filters and the corresponding radio receivers. The circuit techniques that were used in the three gm-C filter implementations of this work are described and a common-mode induced even-order distortion in a pseudo-differential filter is analyzed. Two evolution versions of fifth-order 240-MHz gm-C low-pass filters that were designed and implemented for two single-chip WiMedia UWB direct-conversion receivers in a standard 0.13-µm and 65-nm CMOS technology, respectively, are presented, along with the experimental results of both the low-pass filters and the second receiver version. The second UWB filter design was also embedded with an ADC into the baseband of a 60-GHz 65-nm CMOS radio receiver. In addition, a third-order 1-GHz gm-C low-pass filter was designed, rather as a test structure, for the same receiver. The experimental results of the receiver and the third gm-C filter implementation are presented
Baseband analog circuits in deep-submicron cmos technologies targeted for mobile multimedia
Three main analog circuit building blocks that are important for a mixed-signal
system are investigated in this work. New building blocks with emphasis on power
efficiency and compatibility with deep-submicron technology are proposed and
experimental results from prototype integrated circuits are presented.
Firstly, a 1.1GHz, 5th order, active-LC, Butterworth wideband equalizer that
controls inter-symbol interference and provides anti-alias filtering for the subsequent
analog to digital converter is presented. The equalizer design is based on a new series
LC resonator biquad whose power efficiency is analytically shown to be better than a
conventional Gm-C biquad. A prototype equalizer is fabricated in a standard 0.18μm
CMOS technology. It is experimentally verified to achieve an equalization gain
programmable over a 0-23dB range, 47dB SNR and -48dB IM3 while consuming 72mW
of power. This corresponds to more than 7 times improvement in power efficiency over
conventional Gm-C equalizers.
Secondly, a load capacitance aware compensation for 3-stage amplifiers is
presented. A class-AB 16W headphone driver designed using this scheme in 130nm technology is experimentally shown to handle 1pF to 22nF capacitive load while
consuming as low as 1.2mW of quiescent power. It can deliver a maximum RMS power
of 20mW to the load with -84.8dB THD and 92dB peak SNR, and it occupies a small
area of 0.1mm2. The power consumption is reduced by about 10 times compared to
drivers that can support such a wide range of capacitive loads.
Thirdly, a novel approach to design of ADC in deep-submicron technology is
described. The presented technique enables the usage of time-to-digital converter (TDC)
in a delta-sigma modulator in a manner that takes advantage of its high timing precision
while noise-shaping the error due to its limited time resolution. A prototype ADC
designed based on this deep-submicron technology friendly architecture was fabricated
in a 65nm digital CMOS technology. The ADC is experimentally shown to achieve
68dB dynamic range in 20MHz signal bandwidth while consuming 10.5mW of power. It
is projected to reduce power and improve speed with technology scaling
Low Power Filtering Techniques for Wideband and Wireless Applications
This dissertation presents design and implementation of continuous time analog
filters for two specific applications: wideband analog systems such as disk drive channel
and low-power wireless applications. Specific focus has been techniques that reduce the
power requirements of the overall system either through improvement in architecture or
efficiency of the analog building blocks.
The first problem that this dissertation addresses is the implementation of
wideband filters with high equalization gain. An efficient architecture that realizes
equalization zeros by combining available transfer functions associated with a
biquadratic cell is proposed. A 330MHz, 5th order Gm-C lowpass Butterworth filter with
24dB boost is designed using the proposed architecture. The prototype fabricated in
standard 0.35um CMOS process shows -41dB of IM3 for 250mV peak to peak swing
with 8.6mW/pole of power dissipation. Also, an LC prototype implemented using
similar architecture is discussed in brief. It is shown that, for practical range of frequency and SNR, LC based design is more power efficient than a Gm-C one, though
at the cost of much larger area.
Secondly, a complementary current mirror based building block is proposed,
which pushes the limits imposed by conventional transconductors on the powerefficiency
of Gm-C filters. Signal processing through complementary devices provides
good linearity and Gm/Id efficiency and is shown to improve power efficiency by nearly
7 times. A current-mode 4th order Butterworth filter is designed, in 0.13um UMC
technology, using the proposed building. It provides 54.2dB IM3 and 55dB SNR in
1.3GHz bandwidth while consuming as low as 24mW of power. All CMOS filter
realization occupies a relatively small area and is well suited for integration in deep
submicron technologies.
Thirdly, a 20MHz, 68dB dynamic range active RC filter is presented. This filter
is designed for a ten bit continuous time sigma delta ADC architecture developed
specifically for fine-line CMOS technologies. Inverter based amplification and a
common mode feedback for such amplifiers are discussed. The filter consumes 5mW of
power and occupies an area of 0.07 mm2