The Fault-Tolerant Multiprocessor Computer ePub download
by T. Basil III Smith
- ISBN: 081551087X
- ISBN13: 978-0815510871
- ePub: 1725 kb | FB2: 1593 kb
- Language: English
- Category: Hardware & DIY
- Publisher: Noyes Pubns (May 1, 1986)
- Pages: 750
- Rating: 4.9/5
- Votes: 257
- Format: lrf docx mobi doc
The fault-tolerant multiprocessor computer.
The fault-tolerant multiprocessor computer. This book presents studies of two fault-tolerant computer systems designed to meet the extreme reliability requirements for safety- critical functions in advanced NASA vehicles, plus a study o. More). The Evolution of Fault Tolerant Computing at the Charles Stark Draper Laboratory, 1955–85.
Fault Tolerant Multiprocessor Systems A novel architecture for a fault-tolerance layer for .
Fault Tolerant Multiprocessor Systems. How we measure 'reads'. A novel architecture for a fault-tolerance layer for application reliability on massively parallel computers and distributed computing systems is proposed. This is the first attempt at providing a purely softwarebased, user-level solution for fault detection, reconfiguration, and recovery in a parallel environment. Effective exploitation of a parallel computer system is a result of cooperation between the communication and the computing parts of a parallel computer system, and the application. These elements are described by various parameters.
Fault-tolerant computing became an issue of importance at the Draper .
Fault-tolerant computing became an issue of importance at the Draper Laboratory at the same time that digital computers began to be incorporated into guidance, navigation, and control systems. Part of the Dependable Computing and Fault-Tolerant Systems book series (DEPENDABLECOMP, volume 1). Abstract. Fault-tolerant computing became an issue of importance at the Draper Laboratory at the same time that digital computers began to be incorporated into guidance, navigation, and control systems.
Fault tolerance is particularly sought after in high-availability or life-critical systems.
This book presents studies of two fault-tolerant computer systems designed to meet the extreme reliability requirements for safety- critical functions in advanced NASA vehicles, plus a study of potential architectures for future flight control fault-tolerant systems, which might succeed the current generation of computers. While it is understood that these studies were done for NASA, they also have practical commercial applicability. The fault-tolerant multiprocessor (FTMP) architecture is a high reliability computer concept
The development and evaluation of fault-tolerant computer architectures and fault tolerance (SIFT) for use in advanced NASA vehicles and potentially in flight-control systms are described in a collection of previously published reports prepared for NASA.
FTMP - Fault Tolerant Multiprocessor Computer System Contributor: LaR. ASA Acronyms. Pluribus - The Pluribus multiprocessor was an early multi processor computer designed by BBN for use as a packet switch in the ARPANET. Its design later influenced the BBN Butterfly computer. Plessey - The Plessey Company plc was a British based international electronics, defence and telecommunications company.
Fault-tolerant computer system. Fault-tolerant computer systems are systems designed around the concepts of fault tolerance. In essence, they must be able to continue working to a level of satisfaction in the presence of errors or breakdowns. Fault tolerance is not just a property of individual machines; it may also characterise the rules by which they interact.
Traditionally, fault-tolerant and high-availability systems have been limited . Using the core-level redundancy inherent in chip mUltiprocessors for fault tolerance is a well studied idea.
Traditionally, fault-tolerant and high-availability systems have been limited to the domain of mainframe computers or specially-designed systems like the IBM zSeries and the Compaq NonStop®Advanced Architecture (NSAA). These systems spare no expense to pro vide the highest possible level of reliability.