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Co-Design is the set of emerging techniques which allows for the
simultaneous design of Hardware and Software. In many cases where
the application is very demanding in terms of various performances
(time, surface, power consumption), trade-offs between dedicated
hardware and dedicated software are becoming increasingly difficult
to decide upon in the early stages of a design. Verification
techniques - such as simulation or proof techniques - that have
proven necessary in the hardware design must be dramatically
adapted to the simultaneous verification of Software and Hardware.
Describing the latest tools available for both Co-Design and
Co-Verification of systems, Hardware/Software Co-Design and
Co-Verification offers a complete look at this evolving set of
procedures for CAD environments. The book considers all trade-offs
that have to be made when co-designing a system. Several models are
presented for determining the optimum solution to any co-design
problem, including partitioning, architecture synthesis and code
generation. When deciding on trade-offs, one of the main factors to
be considered is the flow of communication, especially to and from
the outside world. This involves the modeling of communication
protocols. An approach to the synthesis of interface circuits in
the context of co-design is presented. Other chapters present a
co-design oriented flexible component data-base and retrieval
methods; a case study of an ethernet bridge, designed using LOTOS
and co-design methodologies and finally a programmable user
interface based on monitors. Hardware/Software Co-Design and
Co-Verification will help designers and researchers to understand
these latest techniques in system design and as such will be of
interest to all involved in embedded system design.
Object-oriented techniques and languages have been proven to
significantly increase engineering efficiency in software
development. Many benefits are expected from their introduction
into electronic modeling. Among them are better support for model
reusability and flexibility, more efficient system modeling, and
more possibilities in design space exploration and prototyping.
Object-Oriented Modeling explores the latest techniques in
object-oriented methods, formalisms and hardware description
language extensions. The seven chapters comprising this book
provide an overview of the latest object-oriented techniques for
designing systems and hardware. Many examples are given in C++,
VHDL and real-time programming languages. Object-Oriented Modeling
describes further the use of object-oriented techniques in
applications such as embedded systems, telecommunications and
real-time systems, using the very latest techniques in
object-oriented modeling. It is an essential guide to researchers,
practitioners and students involved in software, hardware and
system design.
Models in system design follow the general tendency in electronics
in terms of size, complexity and difficulty of maintenance. While a
model should be a manageable representation of a system, this
increasing complexity sometimes forces current CAD-tool designers
and model writers to apply modeling techniques to the model itself.
Model writers are interested in instrumenting their model, so as to
extract critical information before the model is complete. CAD
tools designers use internal representations of the design at
various stages. The complexity has also led CAD-tool developers to
develop formal tools, theories and methods to improve relevance,
completeness and consistency of those internal representations.
Information modeling involves the representation of objects, their
properties and relationships. Performance Modeling When it comes to
design choices and trade-offs, performance is generally the final
key. However performance estimations have to be extracted at a very
early stage in the system design. Performance modeling concerns the
set of tools and techniques that allow or help the designer to
capture metrics relating to future architectures. Performance
modeling encompasses the whole system, including software modeling.
It has a strong impact on all levels of design choices, from
hardware/software partitioning to the final layout. Information
Modeling Specification and formalism have in the past traditionally
played little part in the design and development of EDA systems,
their support environments, languages and processes. Instead, EDA
system developers and EDA system users have seemed to be content to
operate within environments that are often extremely complex and
may be poorly tested and understood. This situation has now begun
to change with the increasing use of techniques drawn from the
domains of formal specification and database design. This section
of this volume addresses aspects of the techniques being used. In
particular, it considers a specific formalism, called information
modeling, which has gained increasing acceptance recently and is
now a key part of many of the proposals in the EDA Standards
Roadmap, which promises to be of significance to the EDA industry.
In addition, the section looks at an example of a design system
from the point of view of its underlying understanding of the
design process rather than through a consideration of particular
CAD algorithms. Meta-Modeling: Performance and Information Modeling
contains papers describing the very latest techniques used in
meta-modeling. It will be a valuable text for researchers,
practitioners and students involved in Electronic Design
Automation.
The VITAL specification addresses the issues of interoperability,
backannotation and high performance simulation for sign-off quality
ASIC libraries in VHDL. VITAL provides modeling guidelines and a
set of pre-defined packages (containing pre-defined routines for
modeling functionality and timing) to facilitate the acceleration
of designs which use cells from a VITAL library. The VITAL Level-I
guidelines constrain the modeling capabilities provided by VHDL in
order to facilitate higher performance (Figure I). Accumulating
"gains" Constrained "flexibility" Higher performance &
Increased capacity Benefits Flexibility FujI VHDL 1076 Figure 1:
VHDL and VITAL Even within the Level-I guidelines, there are
several ways in which a model can be written. In this chapter, we
highlight the various modeling trade-offs and provide guidelines
which can be used for developing efficient models. We will also
discuss the techniques that can be used by tool developers to
accelerate the simulation of VIT AL based designs. 2.2. OVERVIEW OF
A VITAL LEVEL-l ARCIDTECTURE The VITAL specification is versatile
enough to support several modeling styles e.g., distributed delay
style, pin-to-pin delay style etc. In general, a VITAL Level-I
model can have the structure illustrated in Figure 2."
Hardware description languages (HDL) such as VHDL and Verilog have
found their way into almost every aspect of the design of digital
hardware systems. Since their inception they gradually proved to be
an essential part of modern design methodologies and design
automation tools, ever exceeding their original goals of being
description and simulation languages. Their use for automatic
synthesis, formal proof, and testing are good examples. So far,
HDLs have been mainly dealing with digital systems. However,
integrated systems designed today require more and more analog
parts such as A/D and D/A converters, phase locked loops, current
mirrors, etc. The verification of the complete system therefore
asks for the use of a single language. Using VHDL or Verilog to
handle analog descriptions is possible, as it is shown in this
book, but the real power is coming from true mixed-signal HDLs that
integrate discrete and continuous semantics into a unified
framework. Analog HDLs (AHDL) are considered here a subset of
mixed-signal HDLs as they intend to provide the same level of
features as HDLs do but with a scope limited to analog systems,
possibly with limited support of discrete semantics. Analog and
Mixed-Signal Hardware Description Languages covers several aspects
related to analog and mixed-signal hardware description languages
including: The use of a digital HDL for the description and the
simulation of analog systems The emergence of extensions of
existing standard HDLs that provide true analog and mixed-signal
HDLs. The use of analog and mixed-signal HDLs for the development
of behavioral models of analog (electronic) building blocks
(operational amplifier, PLL) and for the design of microsystems
that do not only involve electronic parts. The use of a front-end
tool that eases the description task with the help of a graphical
paradigm, yet generating AHDL descriptions automatically. Analog
and Mixed-Signal Hardware Description Languages is the first book
to show how to use these new hardware description languages in the
design of electronic components and systems. It is necessary
reading for researchers and designers working in electronic design.
Models in System Design tracks the general trend in electronics in
terms of size, complexity and difficulty of maintenance. System
design is by nature combined with prototyping, mixed domain design,
and verification, and it is no surprise that today's modeling and
models are used in various levels of system design and
verification. In order to deal with constraints induced by volume
and complexity, new methods and techniques have been defined.
Models in System Design provides an overview of the latest modeling
techniques for use by system designers. The first part of the book
considers system level design, discussing such issues as
abstraction, performance and trade-offs. There is also a section on
automating system design. The second part of the book deals with
some of the newest aspects of embedded system design. These include
co-verification and prototyping. Finally, the book includes a
section on the use of the MCSE methodology for hardware/software
co-design. Models in System Design will help designers and
researchers to understand these latest techniques in system design
and as such will be of interest to all involved in embedded system
design.
Modeling in Analog Design highlights some of the most pressing
issues in the use of modeling techniques for design of analogue
circuits. Using models for circuit design gives designers the power
to express directly the behaviour of parts of a circuit in addition
to using other pre-defined components. There are numerous
advantages to this new category of analog behavioral language. In
the short term, by favouring the top-down design and raising the
level of description abstraction, this approach provides greater
freedom of implementation and a higher degree of technology
independence. In the longer term, analog synthesis and formal
optimisation are targeted. Modeling in Analog Design introduces the
reader to two main language standards: VHDL-A and MHDL. It goes on
to provide in-depth examples of the use of these languages to model
analog devices. The final part is devoted to the very important
topic of modeling the thermal and electrothermal aspects of
devices. This book is essential reading for analog designers using
behavioral languages and analog CAD tool development environments
who have to provide the tools used by the designers.
Model Generation in Electronic Design covers a wide range of model
applications and research. The book begins by describing a model
generator to create component models. It goes on to discuss ASIC
design and ASIC library generation. This section includes chapters
on the requirements for developing and ASIC library, a case study
in which VITAL is used to create such a library, and the analysis
and description of the accuracy required in modeling
interconnections in ASIC design. Other chapters describe the
development of thermal models for electronic devices, the
development of a set of model packages for VHDL floating point
operations, a techniques for model validation and verification, and
a tool for model encryption. Model Generation in Electronic Design
is an essential update for users, vendors, model producers,
technical managers, designers and researchers working in electronic
design.
In system design, generation of high-level abstract models that can
be closely associated with evolving lower-level models provides
designers with the ability to incrementally test' an evolving
design against a model of a specification. Such high-level models
may deal with areas such as performance, reliability, availability,
maintainability, and system safety. Abstract models also allow
exploration of the hardware versus software design space in an
incremental fashion as a fuller, detailed design unfolds, leaving
behind the old practice of hardware-software binding too early in
the design process. Such models may also allow the inclusion of
non-functional aspects of design (e.g. space, power, heat) in a
simulatable information model dealing with the system's operation.
This book addresses Model Generation and Application specifically
in the following domains: Specification modeling (linking
object/data modeling, behavior modeling, and activity modeling).
Operational specification modeling (modeling the way the system is
supposed to operate - from a user's viewpoint). Linking
non-functional parameters with specification models. Hybrid
modeling (linking performance and functional elements). Application
of high-level modeling to hardware/software approaches.
Mathematical analysis techniques related to the modeling
approaches. Reliability modeling. Applications of High Level
Modeling. Reducing High Level Modeling to Practice. High-Level
System Modeling: Specification and Design Methodologies describes
the latest research and practice in the modeling of electronic
systems and as such is an important update for all researchers,
design engineers and technical managers working in design
automation and circuit design.
A reactive system is one that is in continual interaction with its
environment and executes at a pace determined by that environment.
Examples of reactive systems are network protocols, air-traffic
control systems, industrial-process control systems etc. Reactive
systems are ubiquitous and represent an important class of systems.
Due to their complex nature, such systems are extremely difficult
to specify and implement. Many reactive systems are employed in
highly-critical applications, making it crucial that one considers
issues such as reliability and safety while designing such systems.
The design of reactive systems is considered to be problematic, and
p.oses one of the greatest challenges in the field of system design
and development. In this paper, we discuss specification-modeling
methodologies for reactive systems. Specification modeling is an
important stage in reactive system design where the designer
specifies the desired properties of the reactive system in the form
of a specification model. This specification model acts as the
guidance and source for the implementation. To develop the
specification model of complex systems in an organized manner,
designers resort to specification modeling methodologies. In the
context of reactive systems, we can call such methodologies
reactive-system specification modeling methodologies.
Hardware description languages (HDL) such as VHDL and Verilog have
found their way into almost every aspect of the design of digital
hardware systems. Since their inception they gradually proved to be
an essential part of modern design methodologies and design
automation tools, ever exceeding their original goals of being
description and simulation languages. Their use for automatic
synthesis, formal proof, and testing are good examples. So far,
HDLs have been mainly dealing with digital systems. However,
integrated systems designed today require more and more analog
parts such as A/D and D/A converters, phase locked loops, current
mirrors, etc. The verification of the complete system therefore
asks for the use of a single language. Using VHDL or Verilog to
handle analog descriptions is possible, as it is shown in this
book, but the real power is coming from true mixed-signal HDLs that
integrate discrete and continuous semantics into a unified
framework. Analog HDLs (AHDL) are considered here a subset of
mixed-signal HDLs as they intend to provide the same level of
features as HDLs do but with a scope limited to analog systems,
possibly with limited support of discrete semantics. Analog and
Mixed-Signal Hardware Description Languages covers several aspects
related to analog and mixed-signal hardware description languages
including: The use of a digital HDL for the description and the
simulation of analog systems The emergence of extensions of
existing standard HDLs that provide true analog and mixed-signal
HDLs. The use of analog and mixed-signal HDLs for the development
of behavioral models of analog (electronic) building blocks
(operational amplifier, PLL) and for the design of microsystems
that do not only involve electronic parts. The use of a front-end
tool that eases the description task with the help of a graphical
paradigm, yet generating AHDL descriptions automatically. Analog
and Mixed-Signal Hardware Description Languages is the first book
to show how to use these new hardware description languages in the
design of electronic components and systems. It is necessary
reading for researchers and designers working in electronic design.
Models in System Design tracks the general trend in electronics in
terms of size, complexity and difficulty of maintenance. System
design is by nature combined with prototyping, mixed domain design,
and verification, and it is no surprise that today's modeling and
models are used in various levels of system design and
verification. In order to deal with constraints induced by volume
and complexity, new methods and techniques have been defined.
Models in System Design provides an overview of the latest modeling
techniques for use by system designers. The first part of the book
considers system level design, discussing such issues as
abstraction, performance and trade-offs. There is also a section on
automating system design. The second part of the book deals with
some of the newest aspects of embedded system design. These include
co-verification and prototyping. Finally, the book includes a
section on the use of the MCSE methodology for hardware/software
co-design. Models in System Design will help designers and
researchers to understand these latest techniques in system design
and as such will be of interest to all involved in embedded system
design.
Model Generation in Electronic Design covers a wide range of model
applications and research. The book begins by describing a model
generator to create component models. It goes on to discuss ASIC
design and ASIC library generation. This section includes chapters
on the requirements for developing and ASIC library, a case study
in which VITAL is used to create such a library, and the analysis
and description of the accuracy required in modeling
interconnections in ASIC design. Other chapters describe the
development of thermal models for electronic devices, the
development of a set of model packages for VHDL floating point
operations, a techniques for model validation and verification, and
a tool for model encryption. Model Generation in Electronic Design
is an essential update for users, vendors, model producers,
technical managers, designers and researchers working in electronic
design.
A reactive system is one that is in continual interaction with its
environment and executes at a pace determined by that environment.
Examples of reactive systems are network protocols, air-traffic
control systems, industrial-process control systems etc. Reactive
systems are ubiquitous and represent an important class of systems.
Due to their complex nature, such systems are extremely difficult
to specify and implement. Many reactive systems are employed in
highly-critical applications, making it crucial that one considers
issues such as reliability and safety while designing such systems.
The design of reactive systems is considered to be problematic, and
p.oses one of the greatest challenges in the field of system design
and development. In this paper, we discuss specification-modeling
methodologies for reactive systems. Specification modeling is an
important stage in reactive system design where the designer
specifies the desired properties of the reactive system in the form
of a specification model. This specification model acts as the
guidance and source for the implementation. To develop the
specification model of complex systems in an organized manner,
designers resort to specification modeling methodologies. In the
context of reactive systems, we can call such methodologies
reactive-system specification modeling methodologies.
Modeling in Analog Design highlights some of the most pressing
issues in the use of modeling techniques for design of analogue
circuits. Using models for circuit design gives designers the power
to express directly the behaviour of parts of a circuit in addition
to using other pre-defined components. There are numerous
advantages to this new category of analog behavioral language. In
the short term, by favouring the top-down design and raising the
level of description abstraction, this approach provides greater
freedom of implementation and a higher degree of technology
independence. In the longer term, analog synthesis and formal
optimisation are targeted. Modeling in Analog Design introduces the
reader to two main language standards: VHDL-A and MHDL. It goes on
to provide in-depth examples of the use of these languages to model
analog devices. The final part is devoted to the very important
topic of modeling the thermal and electrothermal aspects of
devices. This book is essential reading for analog designers using
behavioral languages and analog CAD tool development environments
who have to provide the tools used by the designers.
Object-oriented techniques and languages have been proven to
significantly increase engineering efficiency in software
development. Many benefits are expected from their introduction
into electronic modeling. Among them are better support for model
reusability and flexibility, more efficient system modeling, and
more possibilities in design space exploration and prototyping.
Object-Oriented Modeling explores the latest techniques in
object-oriented methods, formalisms and hardware description
language extensions. The seven chapters comprising this book
provide an overview of the latest object-oriented techniques for
designing systems and hardware. Many examples are given in C++,
VHDL and real-time programming languages. Object-Oriented Modeling
describes further the use of object-oriented techniques in
applications such as embedded systems, telecommunications and
real-time systems, using the very latest techniques in
object-oriented modeling. It is an essential guide to researchers,
practitioners and students involved in software, hardware and
system design.
Hardware Component Modeling highlights the current status of the
modeling of electronic components. It includes contributions from
many of the leading researchers and practitioners in the field. The
contents focus on four important topics. Standards: Three chapters
describe current developments in employing standards for the use of
component libraries. A major part of these chapters provides an
excellent introduction to VITAL (an IEEE standard), its application
and some of the issues in using and implementing it. There are,
however, other standards with a role to play and these are also
covered. Data Types: One chapter describes the latest techniques
for using data types in modeling and simulation. Model Generation:
One chapter describes a model generator for reusable component
models and another describes a generator which takes actual
physical data as its source and generates a functional model.
Quality Assurance: Two chapters are devoted to improving the
quality of models. One introduces a method for quantifying aspects
of model quality and the other introduces quality concepts which
can lead to an increase in model value through reuse and
robustness.Hardware Component Modeling is a valuable reference for
researchers and practitioners involved in the process of modeling
electronic components.
In system design, generation of high-level abstract models that can
be closely associated with evolving lower-level models provides
designers with the ability to incrementally test' an evolving
design against a model of a specification. Such high-level models
may deal with areas such as performance, reliability, availability,
maintainability, and system safety. Abstract models also allow
exploration of the hardware versus software design space in an
incremental fashion as a fuller, detailed design unfolds, leaving
behind the old practice of hardware-software binding too early in
the design process. Such models may also allow the inclusion of
non-functional aspects of design (e.g. space, power, heat) in a
simulatable information model dealing with the system's operation.
This book addresses Model Generation and Application specifically
in the following domains: Specification modeling (linking
object/data modeling, behavior modeling, and activity modeling).
Operational specification modeling (modeling the way the system is
supposed to operate - from a user's viewpoint). Linking
non-functional parameters with specification models. Hybrid
modeling (linking performance and functional elements). Application
of high-level modeling to hardware/software approaches.
Mathematical analysis techniques related to the modeling
approaches. Reliability modeling. Applications of High Level
Modeling. Reducing High Level Modeling to Practice. High-Level
System Modeling: Specification and Design Methodologies describes
the latest research and practice in the modeling of electronic
systems and as such is an important update for all researchers,
design engineers and technical managers working in design
automation and circuit design.
Models in system design follow the general tendency in electronics
in terms of size, complexity and difficulty of maintenance. While a
model should be a manageable representation of a system, this
increasing complexity sometimes forces current CAD-tool designers
and model writers to apply modeling techniques to the model itself.
Model writers are interested in instrumenting their model, so as to
extract critical information before the model is complete. CAD
tools designers use internal representations of the design at
various stages. The complexity has also led CAD-tool developers to
develop formal tools, theories and methods to improve relevance,
completeness and consistency of those internal representations.
Information modeling involves the representation of objects, their
properties and relationships. Performance Modeling When it comes to
design choices and trade-offs, performance is generally the final
key. However performance estimations have to be extracted at a very
early stage in the system design. Performance modeling concerns the
set of tools and techniques that allow or help the designer to
capture metrics relating to future architectures. Performance
modeling encompasses the whole system, including software modeling.
It has a strong impact on all levels of design choices, from
hardware/software partitioning to the final layout. Information
Modeling Specification and formalism have in the past traditionally
played little part in the design and development of EDA systems,
their support environments, languages and processes. Instead, EDA
system developers and EDA system users have seemed to be content to
operate within environments that are often extremely complex and
may be poorly tested and understood. This situation has now begun
to change with the increasing use of techniques drawn from the
domains of formal specification and database design. This section
of this volume addresses aspects of the techniques being used. In
particular, it considers a specific formalism, called information
modeling, which has gained increasing acceptance recently and is
now a key part of many of the proposals in the EDA Standards
Roadmap, which promises to be of significance to the EDA industry.
In addition, the section looks at an example of a design system
from the point of view of its underlying understanding of the
design process rather than through a consideration of particular
CAD algorithms. Meta-Modeling: Performance and Information Modeling
contains papers describing the very latest techniques used in
meta-modeling. It will be a valuable text for researchers,
practitioners and students involved in Electronic Design
Automation.
Co-Design is the set of emerging techniques which allows for the
simultaneous design of Hardware and Software. In many cases where
the application is very demanding in terms of various performances
(time, surface, power consumption), trade-offs between dedicated
hardware and dedicated software are becoming increasingly difficult
to decide upon in the early stages of a design. Verification
techniques - such as simulation or proof techniques - that have
proven necessary in the hardware design must be dramatically
adapted to the simultaneous verification of Software and Hardware.
Describing the latest tools available for both Co-Design and
Co-Verification of systems, Hardware/Software Co-Design and
Co-Verification offers a complete look at this evolving set of
procedures for CAD environments. The book considers all trade-offs
that have to be made when co-designing a system. Several models are
presented for determining the optimum solution to any co-design
problem, including partitioning, architecture synthesis and code
generation. When deciding on trade-offs, one of the main factors to
be considered is the flow of communication, especially to and from
the outside world. This involves the modeling of communication
protocols. An approach to the synthesis of interface circuits in
the context of co-design is presented. Other chapters present a
co-design oriented flexible component data-base and retrieval
methods; a case study of an ethernet bridge, designed using LOTOS
and co-design methodologies and finally a programmable user
interface based on monitors. Hardware/Software Co-Design and
Co-Verification will help designers and researchers to understand
these latest techniques in system design and as such will be of
interest to all involved in embedded system design.
Originally published in 1979, this book is the result of a Wiese
family reunion. Initially, it was merely supposed to cover the
immediate family or the children of Fred and Hulda Wiese. However,
the search quickly expanded to encompass many more family members.
Much of the information was yielded by the living children and
grandchildren of Carl and Minna Wiese who came to the United States
from Germany in 1869, leaving a farm that had been registered since
1689 and is still in the possession of a Chris Wiese. This work is
full of well-documented facts such as: ship's logs, U.S. census
records, church records, and wills. It also includes a genealogical
table, citizenship papers, military records, emigration papers,
family bibles, marriage records, etc. Maps and family photographs
abound. Although the information contained within this book is a
good mix of "both hazy memories as well as documented evidence,"
the author suggests that the reader "take into consideration that
if time and age have distorted the facts and truths, these memories
are better than knowing nothing."
These abstracts include announcements of Masonic Lodge meetings,
legal notices, runaway slaves, marriages and deaths, religious and
community events, court proceedings, legal disputes, estate and tax
sales, military appointments, elections, epidemics, mur
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