A Self-Stabilizing Distributed Approximation Algorithm for the Minimum Connected Dominating Set

Author

Kamei, Sayaka ; Kakugawa, Hirotsugu

Author_Institution

Dept. of Inf. Syst., Tottori Univ. of Environ. Studies, Tottori

fYear

2007

fDate

26-30 March 2007

Firstpage

1

Lastpage

8

Abstract

Self-stabilization is a theoretical framework of non-masking fault-tolerant distributed algorithms. A self-stabilizing system tolerates any kind and any finite number of transient faults, such as message loss, memory corruption, and topology change. Because such transient faults occur so frequently in mobile ad hoc networks, distributed algorithms on them should tolerate such events. In this paper, we propose a self-stabilizing distributed approximation algorithm for the minimum connected dominating set, which can be used, for example, as a virtual backbone or routing in mobile ad hoc networks. The size of the solution by our algorithm is at most 8 |D_opt | + 1, where Dopt is a minimum connected dominating set. The time complexity is O(n²) steps.

Keywords

approximation theory; computational complexity; distributed algorithms; self-adjusting systems; stability; minimum connected dominating set; mobile ad hoc networks; non-masking fault tolerant distributed algorithms; self-stabilization; self-stabilizing distributed approximation algorithm; self-stabilizing system; time complexity; Approximation algorithms; Computer networks; Distributed algorithms; Distributed computing; Fault tolerance; Information systems; Mobile ad hoc networks; Network topology; Routing; Spine;

fLanguage

English

Publisher

ieee

Conference_Titel

Parallel and Distributed Processing Symposium, 2007. IPDPS 2007. IEEE International

Conference_Location

Rome

Print_ISBN

1-4244-0909-8

Electronic_ISBN

1-4244-0910-1

Type

conf

DOI

10.1109/IPDPS.2007.370464

Filename

4228192