Title :
Scalable self-stabilization
Author :
Ghosh, Sukumar ; He, Xin
Author_Institution :
Iowa Univ., Iowa City, IA, USA
Abstract :
The paper presents a method by which an asynchronous non-reactive distributed system can stabilize from a k-faulty configuration in a time that is a monotonically increasing function of k and independent of the size of the system. In the proposed methodology processes first measure the size of the faulty regions, and then use this information to schedule actions in such a way that the faulty regions progressively shrink, until they completely disappear. When k contiguous processes fail, the stabilization time is O(k3). Otherwise, for small values of k, the stabilization time can be exponential in k, but it has an upper bound of O(n3). The added space complexity per process is O(δ log2n), where δ is the maximum degree of a node
Keywords :
computational complexity; configuration management; distributed processing; fault tolerant computing; self-adjusting systems; asynchronous non-reactive distributed system; contiguous processes; faulty regions; k-faulty configuration; monotonically increasing function; scalable self-stabilization; space complexity; stabilization time; Contamination; Helium; Law; Legal factors; Protocols; Read only memory; Size measurement; Upper bound;
Conference_Titel :
Self-Stabilizing Systems, 1999. Proceedings. 19th IEEE International Conference on Distributed Computing Systems Workshop on
Conference_Location :
Austin, TX
Print_ISBN :
0-7695-0228-8
DOI :
10.1109/SLFSTB.1999.777482
