ASIC System Design with VHDL: A Paradigm [electronic resource] /

ASIC System Design with VHDL: A Paradigm [electronic resource] /

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Beginning in the mid 1980's, VLSI technology had begun to advance in two directions. Pushing the limit of integration, ULSI (Ultra Large Scale Integration) represents the frontier of the semiconductor processing technology in the campaign to conquer the submicron realm. The application of ULSI, however, is at present largely confined in the area of memory designs, and as such, its impact on traditional, microprocessor-based system design is modest. If advancement in this direction is merely a natural extrapolation from the previous integration generations, then the rise of ASIC (Application-Specific Integrated Circuit) is an unequivocal signal that a directional change in the discipline of system design is in effect. In contrast to ULSI, ASIC employs only well proven technology, and hence is usually at least one generation behind the most advanced processing technology. In spite of this apparent disadvantage, ASIC has become the mainstream of VLSI design and the technology base of numerous entrepreneurial opportunities ranging from PC clones to supercomputers. Unlike ULSI whose complexity can be hidden inside a memory chip or a standard component and thus can be accommodated by traditional system design methods, ASIC requires system designers to master a much larger body of knowledge spanning from processing technology and circuit techniques to architecture principles and algorithm characteristics. Integrating knowledge in these various areas has become the precondition for integrating devices and functions into an ASIC chip in a market-oriented environment. But knowledge is of two kinds.

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Bibliographic Details
Main Authors: Leung, Steven S. author., Shanblatt, Michael A. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Boston, MA : Springer US, 1989
Subjects:Engineering., Computer hardware., Control engineering., Robotics., Mechatronics., Electrical engineering., Electronic circuits., Circuits and Systems., Electrical Engineering., Control, Robotics, Mechatronics., Computer Hardware.,
Online Access:http://dx.doi.org/10.1007/978-1-4615-6473-7
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id KOHA-OAI-TEST:180199
record_format koha
institution COLPOS
collection Koha
country México
countrycode MX
component Bibliográfico
access En linea
En linea
databasecode cat-colpos
tag biblioteca
region America del Norte
libraryname Departamento de documentación y biblioteca de COLPOS
language eng
topic Engineering.
Computer hardware.
Control engineering.
Robotics.
Mechatronics.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Electrical Engineering.
Control, Robotics, Mechatronics.
Computer Hardware.
Engineering.
Computer hardware.
Control engineering.
Robotics.
Mechatronics.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Electrical Engineering.
Control, Robotics, Mechatronics.
Computer Hardware.
spellingShingle Engineering.
Computer hardware.
Control engineering.
Robotics.
Mechatronics.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Electrical Engineering.
Control, Robotics, Mechatronics.
Computer Hardware.
Engineering.
Computer hardware.
Control engineering.
Robotics.
Mechatronics.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Electrical Engineering.
Control, Robotics, Mechatronics.
Computer Hardware.
Leung, Steven S. author.
Shanblatt, Michael A. author.
SpringerLink (Online service)
ASIC System Design with VHDL: A Paradigm [electronic resource] /
description Beginning in the mid 1980's, VLSI technology had begun to advance in two directions. Pushing the limit of integration, ULSI (Ultra Large Scale Integration) represents the frontier of the semiconductor processing technology in the campaign to conquer the submicron realm. The application of ULSI, however, is at present largely confined in the area of memory designs, and as such, its impact on traditional, microprocessor-based system design is modest. If advancement in this direction is merely a natural extrapolation from the previous integration generations, then the rise of ASIC (Application-Specific Integrated Circuit) is an unequivocal signal that a directional change in the discipline of system design is in effect. In contrast to ULSI, ASIC employs only well proven technology, and hence is usually at least one generation behind the most advanced processing technology. In spite of this apparent disadvantage, ASIC has become the mainstream of VLSI design and the technology base of numerous entrepreneurial opportunities ranging from PC clones to supercomputers. Unlike ULSI whose complexity can be hidden inside a memory chip or a standard component and thus can be accommodated by traditional system design methods, ASIC requires system designers to master a much larger body of knowledge spanning from processing technology and circuit techniques to architecture principles and algorithm characteristics. Integrating knowledge in these various areas has become the precondition for integrating devices and functions into an ASIC chip in a market-oriented environment. But knowledge is of two kinds.
format Texto
topic_facet Engineering.
Computer hardware.
Control engineering.
Robotics.
Mechatronics.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Electrical Engineering.
Control, Robotics, Mechatronics.
Computer Hardware.
author Leung, Steven S. author.
Shanblatt, Michael A. author.
SpringerLink (Online service)
author_facet Leung, Steven S. author.
Shanblatt, Michael A. author.
SpringerLink (Online service)
author_sort Leung, Steven S. author.
title ASIC System Design with VHDL: A Paradigm [electronic resource] /
title_short ASIC System Design with VHDL: A Paradigm [electronic resource] /
title_full ASIC System Design with VHDL: A Paradigm [electronic resource] /
title_fullStr ASIC System Design with VHDL: A Paradigm [electronic resource] /
title_full_unstemmed ASIC System Design with VHDL: A Paradigm [electronic resource] /
title_sort asic system design with vhdl: a paradigm [electronic resource] /
publisher Boston, MA : Springer US,
publishDate 1989
url http://dx.doi.org/10.1007/978-1-4615-6473-7
work_keys_str_mv AT leungstevensauthor asicsystemdesignwithvhdlaparadigmelectronicresource
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spelling KOHA-OAI-TEST:1801992018-07-30T22:59:56ZASIC System Design with VHDL: A Paradigm [electronic resource] / Leung, Steven S. author. Shanblatt, Michael A. author. SpringerLink (Online service) textBoston, MA : Springer US,1989.engBeginning in the mid 1980's, VLSI technology had begun to advance in two directions. Pushing the limit of integration, ULSI (Ultra Large Scale Integration) represents the frontier of the semiconductor processing technology in the campaign to conquer the submicron realm. The application of ULSI, however, is at present largely confined in the area of memory designs, and as such, its impact on traditional, microprocessor-based system design is modest. If advancement in this direction is merely a natural extrapolation from the previous integration generations, then the rise of ASIC (Application-Specific Integrated Circuit) is an unequivocal signal that a directional change in the discipline of system design is in effect. In contrast to ULSI, ASIC employs only well proven technology, and hence is usually at least one generation behind the most advanced processing technology. In spite of this apparent disadvantage, ASIC has become the mainstream of VLSI design and the technology base of numerous entrepreneurial opportunities ranging from PC clones to supercomputers. Unlike ULSI whose complexity can be hidden inside a memory chip or a standard component and thus can be accommodated by traditional system design methods, ASIC requires system designers to master a much larger body of knowledge spanning from processing technology and circuit techniques to architecture principles and algorithm characteristics. Integrating knowledge in these various areas has become the precondition for integrating devices and functions into an ASIC chip in a market-oriented environment. But knowledge is of two kinds.1. Introduction -- 1.1 Problem Statement -- 1.2 Approach -- 1.3 Organization of this Book -- 2. Background -- 2.1 The ASIC Challenge -- 2.2 Computer Architecture Design for Robotic Control -- 2.3 Robotic Kinematics -- 2.4 Summary -- 3. A Conceptual Framework for ASIC Design -- 3.1 The Nature of ASIC Design -- 3.2 The ASIC Design Process -- 3.3 The ASIC Design Hyperspace -- 3.4 The ASIC Design Repertoire -- 3.5 Summary -- 4. The IKS Chip Design Paradigm -- 4.1 Introduction -- 4.2 An ASIC Architecture Design Methodology -- 4.3 The IKS Chip Architecture Design -- 4.4 Summary -- 5. VHDL Simulation of the IKS Chip -- 5.1 Introduction -- 5.2 VHDL Fundamentals -- 5.3 Simulation Objective and Modeling Approach -- 5.4 VHDL Description of the IKS Chip -- 5.5 Simulation Results -- 5.6 Summary -- 6. Conclusion -- 6.1 Summary -- 6.2 Implications and Future Research -- Appendices -- Appendix A. The Closed Form IKS Algorithm for the PUMA -- Appendix B. The IKS Algorithm in Pseudocodes -- Appendix C. Control Signal Definition -- Appendix D. The MACC Encoding Scheme and Code-Maps -- Appendix E. The MACC Microcode for Computing the IKS.Beginning in the mid 1980's, VLSI technology had begun to advance in two directions. Pushing the limit of integration, ULSI (Ultra Large Scale Integration) represents the frontier of the semiconductor processing technology in the campaign to conquer the submicron realm. The application of ULSI, however, is at present largely confined in the area of memory designs, and as such, its impact on traditional, microprocessor-based system design is modest. If advancement in this direction is merely a natural extrapolation from the previous integration generations, then the rise of ASIC (Application-Specific Integrated Circuit) is an unequivocal signal that a directional change in the discipline of system design is in effect. In contrast to ULSI, ASIC employs only well proven technology, and hence is usually at least one generation behind the most advanced processing technology. In spite of this apparent disadvantage, ASIC has become the mainstream of VLSI design and the technology base of numerous entrepreneurial opportunities ranging from PC clones to supercomputers. Unlike ULSI whose complexity can be hidden inside a memory chip or a standard component and thus can be accommodated by traditional system design methods, ASIC requires system designers to master a much larger body of knowledge spanning from processing technology and circuit techniques to architecture principles and algorithm characteristics. Integrating knowledge in these various areas has become the precondition for integrating devices and functions into an ASIC chip in a market-oriented environment. But knowledge is of two kinds.Engineering.Computer hardware.Control engineering.Robotics.Mechatronics.Electrical engineering.Electronic circuits.Engineering.Circuits and Systems.Electrical Engineering.Control, Robotics, Mechatronics.Computer Hardware.Springer eBookshttp://dx.doi.org/10.1007/978-1-4615-6473-7URN:ISBN:9781461564737

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