Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /

Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /

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Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog explains how you can write Verilog to describe chip designs at the RT-level in a manner that cooperates with verification processes. This cooperation can return an order of magnitude improvement in performance and capacity from tools such as simulation and equivalence checkers. It reduces the labor costs of coverage and formal model checking by facilitating communication between the design engineer and the verification engineer. It also orients the RTL style to provide more useful results from the overall verification process. The intended audience for Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is engineers and students who need an introduction to various design verification processes and a supporting functional Verilog RTL coding style. A second intended audience is engineers who have been through introductory training in Verilog and now want to develop good RTL writing practices for verification. A third audience is Verilog language instructors who are using a general text on Verilog as the course textbook but want to enrich their lectures with an emphasis on verification. A fourth audience is engineers with substantial Verilog experience who want to improve their Verilog practice to work better with RTL Verilog verification tools. A fifth audience is design consultants searching for proven verification-centric methodologies. A sixth audience is EDA verification tool implementers who want some suggestions about a minimal Verilog verification subset. Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is based on the reality that comes from actual large-scale product design process and tool experience.

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Bibliographic Details
Main Authors: Bening, Lionel. author., Foster, Harry. author., SpringerLink (Online service)
Format: Texto biblioteca
Language:eng
Published: Boston, MA : Springer US, 2000
Subjects:Engineering., Computer hardware., Computer-aided engineering., Electrical engineering., Electronic circuits., Circuits and Systems., Computer Hardware., Computer-Aided Engineering (CAD, CAE) and Design., Electrical Engineering.,
Online Access:http://dx.doi.org/10.1007/b116517
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id KOHA-OAI-TEST:173586
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.
Computer-aided engineering.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Computer Hardware.
Computer-Aided Engineering (CAD, CAE) and Design.
Electrical Engineering.
Engineering.
Computer hardware.
Computer-aided engineering.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Computer Hardware.
Computer-Aided Engineering (CAD, CAE) and Design.
Electrical Engineering.
spellingShingle Engineering.
Computer hardware.
Computer-aided engineering.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Computer Hardware.
Computer-Aided Engineering (CAD, CAE) and Design.
Electrical Engineering.
Engineering.
Computer hardware.
Computer-aided engineering.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Computer Hardware.
Computer-Aided Engineering (CAD, CAE) and Design.
Electrical Engineering.
Bening, Lionel. author.
Foster, Harry. author.
SpringerLink (Online service)
Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /
description Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog explains how you can write Verilog to describe chip designs at the RT-level in a manner that cooperates with verification processes. This cooperation can return an order of magnitude improvement in performance and capacity from tools such as simulation and equivalence checkers. It reduces the labor costs of coverage and formal model checking by facilitating communication between the design engineer and the verification engineer. It also orients the RTL style to provide more useful results from the overall verification process. The intended audience for Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is engineers and students who need an introduction to various design verification processes and a supporting functional Verilog RTL coding style. A second intended audience is engineers who have been through introductory training in Verilog and now want to develop good RTL writing practices for verification. A third audience is Verilog language instructors who are using a general text on Verilog as the course textbook but want to enrich their lectures with an emphasis on verification. A fourth audience is engineers with substantial Verilog experience who want to improve their Verilog practice to work better with RTL Verilog verification tools. A fifth audience is design consultants searching for proven verification-centric methodologies. A sixth audience is EDA verification tool implementers who want some suggestions about a minimal Verilog verification subset. Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is based on the reality that comes from actual large-scale product design process and tool experience.
format Texto
topic_facet Engineering.
Computer hardware.
Computer-aided engineering.
Electrical engineering.
Electronic circuits.
Engineering.
Circuits and Systems.
Computer Hardware.
Computer-Aided Engineering (CAD, CAE) and Design.
Electrical Engineering.
author Bening, Lionel. author.
Foster, Harry. author.
SpringerLink (Online service)
author_facet Bening, Lionel. author.
Foster, Harry. author.
SpringerLink (Online service)
author_sort Bening, Lionel. author.
title Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /
title_short Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /
title_full Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /
title_fullStr Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /
title_full_unstemmed Principles of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog /
title_sort principles of verifiable rtl design [electronic resource] : a functional coding style supporting verification processes in verilog /
publisher Boston, MA : Springer US,
publishDate 2000
url http://dx.doi.org/10.1007/b116517
work_keys_str_mv AT beninglionelauthor principlesofverifiablertldesignelectronicresourceafunctionalcodingstylesupportingverificationprocessesinverilog
AT fosterharryauthor principlesofverifiablertldesignelectronicresourceafunctionalcodingstylesupportingverificationprocessesinverilog
AT springerlinkonlineservice principlesofverifiablertldesignelectronicresourceafunctionalcodingstylesupportingverificationprocessesinverilog
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spelling KOHA-OAI-TEST:1735862018-07-30T22:51:15ZPrinciples of Verifiable RTL Design [electronic resource] : A Functional Coding Style Supporting Verification Processes in Verilog / Bening, Lionel. author. Foster, Harry. author. SpringerLink (Online service) textBoston, MA : Springer US,2000.engPrinciples of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog explains how you can write Verilog to describe chip designs at the RT-level in a manner that cooperates with verification processes. This cooperation can return an order of magnitude improvement in performance and capacity from tools such as simulation and equivalence checkers. It reduces the labor costs of coverage and formal model checking by facilitating communication between the design engineer and the verification engineer. It also orients the RTL style to provide more useful results from the overall verification process. The intended audience for Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is engineers and students who need an introduction to various design verification processes and a supporting functional Verilog RTL coding style. A second intended audience is engineers who have been through introductory training in Verilog and now want to develop good RTL writing practices for verification. A third audience is Verilog language instructors who are using a general text on Verilog as the course textbook but want to enrich their lectures with an emphasis on verification. A fourth audience is engineers with substantial Verilog experience who want to improve their Verilog practice to work better with RTL Verilog verification tools. A fifth audience is design consultants searching for proven verification-centric methodologies. A sixth audience is EDA verification tool implementers who want some suggestions about a minimal Verilog verification subset. Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is based on the reality that comes from actual large-scale product design process and tool experience.The Verification Process -- RTL Methodology Basics -- RTL Logic Simulation -- RTL Formal Verification -- Verifiable RTL Style -- The Bad Stuff -- Verifiable RTL Tutorial -- Principles of Verifiable RTL Design.Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog explains how you can write Verilog to describe chip designs at the RT-level in a manner that cooperates with verification processes. This cooperation can return an order of magnitude improvement in performance and capacity from tools such as simulation and equivalence checkers. It reduces the labor costs of coverage and formal model checking by facilitating communication between the design engineer and the verification engineer. It also orients the RTL style to provide more useful results from the overall verification process. The intended audience for Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is engineers and students who need an introduction to various design verification processes and a supporting functional Verilog RTL coding style. A second intended audience is engineers who have been through introductory training in Verilog and now want to develop good RTL writing practices for verification. A third audience is Verilog language instructors who are using a general text on Verilog as the course textbook but want to enrich their lectures with an emphasis on verification. A fourth audience is engineers with substantial Verilog experience who want to improve their Verilog practice to work better with RTL Verilog verification tools. A fifth audience is design consultants searching for proven verification-centric methodologies. A sixth audience is EDA verification tool implementers who want some suggestions about a minimal Verilog verification subset. Principles of Verifiable RTL Design: A Functional Coding Style Supporting Verification Processes in Verilog is based on the reality that comes from actual large-scale product design process and tool experience.Engineering.Computer hardware.Computer-aided engineering.Electrical engineering.Electronic circuits.Engineering.Circuits and Systems.Computer Hardware.Computer-Aided Engineering (CAD, CAE) and Design.Electrical Engineering.Springer eBookshttp://dx.doi.org/10.1007/b116517URN:ISBN:9780306470165

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