Energy Conservation in Sensor Networks through Selective Node Activation
WOWMOM '06 Proceedings of the 2006 International Symposium on on World of Wireless, Mobile and Multimedia Networks
Design and Performance Evaluation of Efficient Consensus Protocols for Mobile Ad Hoc Networks
IEEE Transactions on Computers
Analytical model for optimizing periodic route maintenance in proactive routing for manets
Proceedings of the 10th ACM Symposium on Modeling, analysis, and simulation of wireless and mobile systems
Node density control for maximizing wireless sensor network lifetime
International Journal of Network Management
Self-managing energy-efficient multicast support in MANETs under end-to-end reliability constraints
Computer Networks: The International Journal of Computer and Telecommunications Networking
Energy scaling laws for distributed inference in random fusion networks
IEEE Journal on Selected Areas in Communications - Special issue on stochastic geometry and random graphs for the analysis and designof wireless networks
Performance evaluation of efficient and reliable routing protocols for fixed-power sensor networks
IEEE Transactions on Wireless Communications
Minimizing effective energy consumption in multi-cluster sensor networks for source extraction
IEEE Transactions on Wireless Communications
On the endogenous formation of energy efficient cooperative wireless networks
Allerton'09 Proceedings of the 47th annual Allerton conference on Communication, control, and computing
Energy efficiency optimization of cooperative communication in wireless sensor networks
EURASIP Journal on Wireless Communications and Networking - Special issue on theoretical and algorithmic foundations of wireless ad hoc and sensor networks
On some current results of graph theory for ad-hoc networks
Journal of Mobile Multimedia
Hi-index | 0.08 |
An analytical approach to the characterization of energy consumption of large-scale wireless networks is presented. The radio model includes energy consumption of nodes at various operating states. We analyze the total energy consumption of the proactive and the reactive networking strategies, taking into account transmitting, listening, and sleeping energy. Scaling laws with respect to the increase of node density and geographical size are derived. Energy efficiency and overhead at the physical and the network layers are evaluated against message duty cycle, channel fading rate, and node mobility. The crossover point in message duty cycle below which reactive network has assured advantages is obtained. The analysis is then applied to large-scale sensor networks for applications involving data-centric and location-centric queries. The ad hoc sensor network architecture is compared with sensor networks with mobile access points.