Title :
Efficient implementation strategies for the DRB approach in fault-tolerant hypercubes
Author :
Williams, Trevor ; Tan, Jack ; Liang, Chungti
Author_Institution :
Dept. of Comput. Sci., Wisconsin Univ., Eau Claire, WI, USA
Abstract :
The distributed recovery block (DRB) is an efficient approach for the uniform treatment of hardware and software faults in real-time applications. Full DRB mapping assigns each task of an application tasks graph to run on a pair of processor nodes. The primary cost factors that determine its efficiency are dilation bound, expansion factor and congestion. In this paper, two alternative schemes are described that improves the DRB approach. The first describes a mapping of application tasks such that each node in the hypercube executes one or more application tasks in the lifetime of a task graph. The second scheme incorporates spare processors to provide an efficient architecture for implementing the DRB approach
Keywords :
fault tolerant computing; graph theory; hypercube networks; parallel architectures; real-time systems; system recovery; DRB approach; application tasks graph; congestion; dilation bound; distributed recovery block approach; expansion factor; fault-tolerant hypercubes; hardware faults; implementation strategies; primary cost factors; processor nodes; real-time applications; software faults; spare processors; Application software; Binary trees; Computer architecture; Computer science; Costs; Fault tolerance; Hardware; Hypercubes; Lifting equipment; Performance analysis;
Conference_Titel :
Computer Software and Applications Conference, 1997. COMPSAC '97. Proceedings., The Twenty-First Annual International
Conference_Location :
Washington, DC
Print_ISBN :
0-8186-8105-5
DOI :
10.1109/CMPSAC.1997.625085
