Title :
Reconfigurability and reliability of systolic/wavefront arrays
Author :
Sha, Edwin Hsing-Mean ; Steiglitz, Kenneth
Author_Institution :
Dept. of Comput. Sci., Princeton Univ., NJ, USA
Abstract :
Fault-tolerant redundant structures for maintaining reliable arrays are studied. It is assumed that the desired array (application graph) is embedded in a certain class of regular, bounded-degree graphs called dynamic graphs. The authors define the degree of reconfigurability (DR), and DR with distance DRd of a redundant graph. When DR (respectively DRd) is independent of the size of the application graph, it is said that the graph is finitely reconfigurable, FR (resp. locally reconfigurable, LR). It is shown that DR provides a natural lower bound on the time complexity of any distributed reconfiguration algorithm, and that there is no difference between being FR and LR on dynamic graphs. It is then shown that if one wishes to maintain both local reconfigurability and a fixed level of reliability, a dynamic graph must be of dimension at least one greater than the application graph
Keywords :
computational complexity; fault tolerant computing; graph theory; systolic arrays; application graph; array reliability; bounded-degree graphs; distributed reconfiguration algorithm; dynamic graphs; fault tolerant computing; finitely reconfigurable; locally reconfigurable; natural lower bound; reconfigurability degree; redundant graph; systolic/wavefront arrays; time complexity; Application software; Computer architecture; Computer science; Costs; Fault tolerance; Maintenance; Signal processing algorithms; Switches; Systolic arrays; Throughput;
Conference_Titel :
Acoustics, Speech, and Signal Processing, 1991. ICASSP-91., 1991 International Conference on
Conference_Location :
Toronto, Ont.
Print_ISBN :
0-7803-0003-3
DOI :
10.1109/ICASSP.1991.150511
