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This book describes a circuit architecture for converting real
analog signals into a digital format, suitable for digital signal
processors. This architecture, referred to as multi-stage
noise-shaping (MASH) Continuous-Time Sigma-Delta Modulators (CT-
M), has the potential to provide better digital data quality and
achieve better data rate conversion with lower power consumption.
The authors not only cover MASH continuous-time sigma delta
modulator fundamentals, but also provide a literature review that
will allow students, professors, and professionals to catch up on
the latest developments in related technology.
This book describes several techniques to address
variation-related design challenges for analog blocks in
mixed-signal systems-on-chip. The methods presented are results
from recent research works involving receiver front-end circuits,
baseband filter linearization, and data conversion. These
circuit-level techniques are described, with their relationships to
emerging system-level calibration approaches, to tune the
performances of analog circuits with digital assistance or control.
Coverage also includes a strategy to utilize on-chip temperature
sensors to measure the signal power and linearity characteristics
of analog/RF circuits, as demonstrated by test chip measurements.
Describes a variety of variation-tolerant analog circuit design
examples, including from RF front-ends, high-performance ADCs and
baseband filters;Includes built-in testing techniques, linked to
current industrial trends;Balances digitally-assisted performance
tuning with analog performance tuning and mismatch reduction
approaches;Describes theoretical concepts as well as experimental
results for test chips designed with variation-aware
techniques."
This book describes several techniques to address
variation-related design challenges for analog blocks in
mixed-signal systems-on-chip. The methods presented are results
from recent research works involving receiver front-end circuits,
baseband filter linearization, and data conversion. These
circuit-level techniques are described, with their relationships to
emerging system-level calibration approaches, to tune the
performances of analog circuits with digital assistance or control.
Coverage also includes a strategy to utilize on-chip temperature
sensors to measure the signal power and linearity characteristics
of analog/RF circuits, as demonstrated by test chip measurements.
Describes a variety of variation-tolerant analog circuit design
examples, including from RF front-ends, high-performance ADCs and
baseband filters;Includes built-in testing techniques, linked to
current industrial trends;Balances digitally-assisted performance
tuning with analog performance tuning and mismatch reduction
approaches;Describes theoretical concepts as well as experimental
results for test chips designed with variation-aware
techniques."
High-Performance CMOS Continuous-Time Filters is devoted to the
design of CMOS continuous-time filters. CMOS is employed because
the most complex integrated circuits have been realized with this
technology for two decades. The most important advantages and
drawbacks of continuous-time filters are clearly shown. The
transfer function is one of the most important filter parameters
but several others (like intermodulation distortion, power-supply
rejection ratio, noise level and dynamic range) are fundamental in
the design of high-performance systems. Special attention is paid
to the practical aspects of the design, which shows the difference
between an academic design and an industrial design. A clear
understanding of the behavior of the circuits and techniques is
preferred over complex equations or interpretation of simulated
results. Step-by-step design procedures are very often used to
clarify the use of the techniques and topologies. The organization
of this text is hierarchical, starting with the design
consideration of the basic building blocks and ending with the
design of several high-performance continuous-time filters. Most of
the circuits have been fabricated, theoretically analyzed and
simulated, and silicon measurement results are compared with each
other. High-Performance CMOS Continuous-Time Filters can be used as
a text book for senior or graduate courses on this topic and can
also be useful for industrial engineers as a reference book.
High-Performance CMOS Continuous-Time Filters is devoted to the
design of CMOS continuous-time filters. CMOS is employed because
the most complex integrated circuits have been realized with this
technology for two decades. The most important advantages and
drawbacks of continuous-time filters are clearly shown. The
transfer function is one of the most important filter parameters
but several others (like intermodulation distortion, power-supply
rejection ratio, noise level and dynamic range) are fundamental in
the design of high-performance systems. Special attention is paid
to the practical aspects of the design, which shows the difference
between an academic design and an industrial design. A clear
understanding of the behavior of the circuits and techniques is
preferred over complex equations or interpretation of simulated
results. Step-by-step design procedures are very often used to
clarify the use of the techniques and topologies. The organization
of this text is hierarchical, starting with the design
consideration of the basic building blocks and ending with the
design of several high-performance continuous-time filters. Most of
the circuits have been fabricated, theoretically analyzed and
simulated, and silicon measurement results are compared with each
other. High-Performance CMOS Continuous-Time Filters can be used as
a text book for senior or graduate courses on this topic and can
also be useful for industrial engineers as a reference book.
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