Title :
Fast convergence in self-stabilizing wireless networks
Author :
Mitton, N. ; Fleury, E. ; Lassous, I. Guérin ; Sericola, B. ; Tixeuil, S.
Author_Institution :
INRIA ARES/INSA, Lyon
Abstract :
The advent of large scale multi-hop wireless networks highlights problems of fault tolerance and scale in distributed systems, motivating designs that autonomously recover from transient faults and spontaneous reconfigurations. Self-stabilization provides an elegant solution for recovering from such faults. We present a complexity analysis for a family of self-stabilizing vertex coloring algorithms in the context of multi-hop wireless networks. Such "coloring" processes are used in several protocols for solving many different issues (clustering, synchronizing...). Overall, our results show that the actual stabilization time is much smaller than the upper bound provided by previous studies. Similarly, the height of the induced DAG is much lower than the linear dependency on the size of the color domain (that was previously announced). Finally, it appears that symmetry breaking tricks traditionally used to expedite stabilization are in fact harmful when used in networks that are not tightly synchronized
Keywords :
computational complexity; directed graphs; fault tolerance; graph colouring; mobile radio; complexity analysis; distributed systems; fault tolerance; induced DAG; large scale multihop wireless networks; self-stabilizing vertex coloring; self-stabilizing wireless networks; spontaneous reconfigurations; transient faults; Algorithm design and analysis; Clustering algorithms; Convergence; Fault tolerant systems; Intelligent networks; Large-scale systems; Protocols; Spread spectrum communication; Upper bound; Wireless networks; coloring; multihop wireless networks; scheduling; stabilization time;
Conference_Titel :
Parallel and Distributed Systems, 2006. ICPADS 2006. 12th International Conference on
Conference_Location :
Minneapolis, MN
Print_ISBN :
0-7695-2612-8
DOI :
10.1109/ICPADS.2006.47
