Energy-Efficient Communication Protocol for Wireless Microsensor Networks
HICSS '00 Proceedings of the 33rd Hawaii International Conference on System Sciences-Volume 8 - Volume 8
BlueMesh: degree-constrained multi-hop scatternet formation for Bluetooth networks
Mobile Networks and Applications
Partial Delaunay Triangulation and Degree Limited Localized Bluetooth Scatternet Formation
IEEE Transactions on Parallel and Distributed Systems
An On-Demand Bluetooth Scatternet Formation and Routing Protocol for Wireless Sensor Networks
SNPD-SAWN '05 Proceedings of the Sixth International Conference on Software Engineering, Artificial Intelligence, Networking and Parallel/Distributed Computing and First ACIS International Workshop on Self-Assembling Wireless Networks
Distributed Construction and Maintenance of Bandwidth and Energy Efficient Bluetooth Scatternets
IEEE Transactions on Parallel and Distributed Systems
Bottom-Up Construction of Bluetooth Topology under a Traffic-Aware Scheduling Scheme
IEEE Transactions on Mobile Computing
TARP: A traffic-aware restructuring protocol for Bluetooth radio networks
Computer Networks: The International Journal of Computer and Telecommunications Networking
Bluetooth scatternets: criteria, models and classification
Ad Hoc Networks
A distributed self-healing approach to Bluetooth scatternet formation
IEEE Transactions on Wireless Communications
Configuring BlueStars: multihop scatternet formation for Bluetooth networks
IEEE Transactions on Computers
IEEE Journal on Selected Areas in Communications
Distributed topology construction of Bluetooth wireless personal area networks
IEEE Journal on Selected Areas in Communications
Dynamic Congestion Control through backup relay in Bluetooth scatternet
Journal of Network and Computer Applications
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Bluetooth is a communication technology for personal area networks (PANs). To support communication with more than eight bluetooth-enabled devices, a scatternet must be formed in the PAN. Bluetree is one commonly used topology for scatternet formation. To reduce traffic load of the Bluetree scatternet, we use the piconet transfer concept to move piconets on a well-formed Bluetree scatternet. The piconet movements are performed based on a distributed manner using two well-known tree traversal procedures: post-order traversal and level-order traversal. These two procedures do not take much computation time, where time complexities are O(n"p) and n"p is the number of piconets on a Bluetree scatternet (not the number of nodes on a Bluetree). Compared with previous approaches, the proposed approach can greatly reduce the traffic load and computational costs. Finally, simulation experiments show the effectiveness of the proposed approach in improving the formation of Bluetree scatternet.