Title :
Design of a highly reliable cube-connected cycles architecture
Author :
Tzeng, Nian-Feng
Author_Institution :
Center for Adv. Comput. Studies, Univ. of Southwestern Louisiana, Lafayette, LA, USA
Abstract :
The cube-connected cycles (CCC) architecture is an attractive supercomputer system, because it not only preserves all the desired features of hypercubes but also is suitable for VLSI implementation. However, the CCC tends to suffer from considerable performance degradation when a fault arises. This paper introduces a fault-tolerant CCC constructed from adding a spare PE to every cycle and making "cross connections" among cycles, called the XCCG. The reconfiguration procedure for the XCCG is simple and can be done in a distributed manner. The XCCG is shown to exhibit significantly enhanced reliability. The XGCG layout is discussed, and its area overhead is found to be moderate if the PE size is far larger than the link/switch size. As a result, this design approach is particularly useful for situations where the PE is relatively complex.
Keywords :
fault tolerant computing; multiprocessor interconnection networks; parallel architectures; VLSI; cross connection; cube connected cycles architecture; fault tolerant cube connected cycles; hypercubes; link size; performance degradation; processing element; supercomputer system; switch size; wafer scale integration; Degradation; Fault tolerance; Hypercubes; Supercomputers; Switches; Very large scale integration;
Conference_Titel :
Supercomputing, 1991. Supercomputing '91. Proceedings of the 1991 ACM/IEEE Conference on
Conference_Location :
Albuquerque, NM
Print_ISBN :
0-89791-459-7
DOI :
10.1145/125826.126184
