Title :
Fault-tolerant cube graphs and coding theory
Author :
Bruck, Jehoshua ; Ho, Ching-Tien
Author_Institution :
California Inst. of Technol., Pasadena, CA, USA
fDate :
11/1/1996 12:00:00 AM
Abstract :
Hypercubes, meshes, tori, and Omega networks are well-known interconnection networks for parallel computers. The structure of those graphs can be described in a more general framework called cube graphs. The idea is to assume that every node in a graph with ql nodes is represented by a unique string of l symbols over GF(q). The edges are specified by a set of offsets, those are vectors of length l over GF(q), where the two endpoints of an edge are an offset apart. We study techniques for tolerating edge faults in cube graphs that are based on adding redundant edges. The redundant graph has the property that the structure of the original graph can be maintained in the presence of edge faults. Our main contribution is a technique for adding the redundant edges that utilizes constructions of error-correcting codes and generalizes existing ad hoc techniques
Keywords :
error correction codes; fault tolerant computing; graph theory; hypercube networks; network topology; parallel architectures; redundancy; Omega networks; coding theory; edge faults; endpoints; error-correcting codes; fault-tolerant cube graphs; hypercubes; interconnection networks; meshes; offset; parallel computers; redundant edges; redundant graph; tori; vectors; Algorithm design and analysis; Costs; Error correction codes; Fault tolerance; Hamming weight; Hypercubes; Iron; Network topology; Parity check codes; USA Councils;
Journal_Title :
Information Theory, IEEE Transactions on
