Title :
Distributed mobility control for fault-tolerant mobile networks
Author_Institution :
Xerox Innovation Group, Webster, NY, USA
Abstract :
Large-scale networks of mobile agents autonomously performing long-term sensing and communication tasks will be foreseeable in the near future. Since nodes in such a system communicate in a multi-hop fashion and the environment may be constantly changing due to the mobility, it is important for such a system to be able to tolerate temporary node failures. Moreover it would be ideal if the communications between nodes are not interrupted while nodes are moving around. In this paper we present a provably correct distributed rendezvous algorithm to achieve both goals by making the underlying communication graph biconnected. The proposed algorithm only requires relative position information of each node and works both synchronously and asynchronously. We further propose for each node a sleep/awake power control schedule in conjunction with the node´s mobility strategy to compensate the energy consumption due to the node´s movement.
Keywords :
distributed algorithms; distributed control; fault tolerance; graph theory; mobile agents; mobile radio; telecommunication control; telecommunication network topology; asynchronous algorithm; bi-connected graph; communication network topology; communication tasks; distributed mobility control; distributed rendezvous algorithm; fault-tolerant mobile networks; large-scale networks; long-term sensing tasks; mobile agents; mobility strategy; multi-hop wireless mobile networks; sleep/awake power control schedule; synchronous algorithm; temporary node failures; Communication system control; Distributed control; Electronic mail; Fault tolerance; Mobile communication; Network topology; Power control; Routing; Sleep; Technological innovation;
Conference_Titel :
Systems Communications, 2005. Proceedings
Print_ISBN :
0-7695-2422-2
DOI :
10.1109/ICW.2005.42
