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Modern telecommunication systems are highly complex from an
algorithmic point of view. The complexity continues to increase due
to advanced modulation schemes, multiple protocols and standards,
as well as additional functionality such as personal organizers or
navigation aids. To have short and reliable design cycles,
efficient verification methods and tools are necessary. Modeling
and simulation need to accompany the design steps from the
specification to the overall system verification in order to bridge
the gaps between system specification, system simulation, and
circuit level simulation. Very high carrier frequencies together
with long observation periods result in extremely large computation
times and requires, therefore, specialized modeling methods and
simulation tools on all design levels. The focus of Modeling and
Simulation for RF System Design lies on RF specific modeling and
simulation methods and the consideration of system and circuit
level descriptions. It contains application-oriented training
material for RF designers which combines the presentation of a
mixed-signal design flow, an introduction into the powerful
standardized hardware description languages VHDL-AMS and Verilog-A,
and the application of commercially available simulators. Modeling
and Simulation for RF System Design is addressed to graduate
students and industrial professionals who are engaged in
communication system design and want to gain insight into the
system structure by own simulation experiences. The authors are
experts in design, modeling and simulation of communication systems
engaged at the Nokia Research Center (Bochum, Germany) and the
Fraunhofer Institute for Integrated Circuits, Branch Lab Design
Automation (Dresden, Germany).
Uncertainty in key parameters within a chip and between different
chips in the deep sub micron area plays a more and more important
role. As a result, manufacturing process spreads need to be
considered during the design process. Quantitative methodology is
needed to ensure faultless functionality, despite existing process
variations within given bounds, during product development. This
book presents the technological, physical, and mathematical
fundamentals for a design paradigm shift, from a deterministic
process to a probability-orientated design process for
microelectronic circuits. Readers will learn to evaluate the
different sources of variations in the design flow in order to
establish different design variants, while applying appropriate
methods and tools to evaluate and optimize their design.
Uncertainty in key parameters within a chip and between different
chips in the deep sub micron area plays a more and more important
role. As a result, manufacturing process spreads need to be
considered during the design process. Quantitative methodology is
needed to ensure faultless functionality, despite existing process
variations within given bounds, during product development. This
book presents the technological, physical, and mathematical
fundamentals for a design paradigm shift, from a deterministic
process to a probability-orientated design process for
microelectronic circuits. Readers will learn to evaluate the
different sources of variations in the design flow in order to
establish different design variants, while applying appropriate
methods and tools to evaluate and optimize their design.
Modern telecommunication systems are highly complex from an
algorithmic point of view. The complexity continues to increase due
to advanced modulation schemes, multiple protocols and standards,
as well as additional functionality such as personal organizers or
navigation aids.
To have short and reliable design cycles, efficient verification
methods and tools are necessary. Modeling and simulation need to
accompany the design steps from the specification to the overall
system verification in order to bridge the gaps between system
specification, system simulation, and circuit level simulation.
Very high carrier frequencies together with long observation
periods result in extremely large computation times and requires,
therefore, specialized modeling methods and simulation tools on all
design levels.
The focus of Modeling and Simulation for RF System Design lies
on RF specific modeling and simulation methods and the
consideration of system and circuit level descriptions. It contains
application-oriented training material for RF designers which
combines the presentation of a mixed-signal design flow, an
introduction into the powerful standardized hardware description
languages VHDL-AMS and Verilog-A, and the application of
commercially available simulators.
Models are provided on a CD-ROM included with the book because
models are necessary to reproduce, understand and explore the real
world behavior on a simulation platform. Modeling and Simulation
for RF System Design is addressed to graduate students and
industrial professionals who are engaged in communication system
design and want to gain insight into the system structure by own
simulation experiences.
The authors areexperts in design, modeling and simulation of
communication systems engaged at the Nokia Research Center (Bochum,
Germany) and the Fraunhofer Institute for Integrated Circuits,
Branch Lab Design Automation (Dresden, Germany).
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