Title :
Structural fault tolerance in VLSI-based systems
Author :
Hung-Kuei-Ku ; Hayes, John P.
Author_Institution :
Dept. of Electr. Eng. & Comput. Sci., Michigan Univ., Ann Arbor, MI, USA
Abstract :
A system is structurally fault-tolerant (SFT) if it preserves a fault-free subsystem of a pre-determined interconnection structure when faults appear. We present a systematic approach to designing SFT VLSI-based systems that use shared buses as the main communication mechanism. To represent the target systems, we introduce a processor-bus-link (PBL) graph in which processing elements (PEs) and buses are both modeled as nodes. PE and bus faults correspond to the removal of nodes from the PBL graph. The node covering concept and the minimum-weight spanning arborescence algorithm are then applied to the design of SFT systems that can tolerate both PE and bus faults. The designs obtained have fewer spare communication ports than prior designs, no critical single point of failure, and simple circuitry for reconfiguration
Keywords :
VLSI; circuit layout; failure analysis; fault tolerant computing; graph theory; hypercube networks; reliability theory; VLSI-based systems; bus faults; fault-free subsystem; hypercubes; minimum-weight spanning arborescence algorithm; node modeling; predetermined interconnection structure; processing elements; processor-bus-link graph; reconfiguration circuitry; shared buses; spare communication ports; structural fault tolerance; two layer VLSI layout; Algorithm design and analysis; Circuit faults; Computer architecture; Design methodology; Fault tolerant systems; Integrated circuit interconnections; Laboratories; Multiplexing; Reconfigurable logic; Very large scale integration;
Conference_Titel :
VLSI, 1994. Design Automation of High Performance VLSI Systems. GLSV '94, Proceedings., Fourth Great Lakes Symposium on
Conference_Location :
Notre Dame, IN
Print_ISBN :
0-8186-5610-7
DOI :
10.1109/GLSV.1994.289996
