Abstract
Due to the combination of constrained power, low duty cycle, and high mobility, neighbor discovery is one of the most challenging problems in wireless sensor networks. Existing discovery designs can be divided into two types: pairwise-based and group-based. The former schemes suffer from high discovery delay, while the latter ones accelerate the discovery process but incur too much energy overhead, far from practical. In this article, we propose a novel efficient group-based discovery method based on relative distance, which makes a delicate trade-off between discovery delay and energy consumption. Instead of directly referring to the wake-up schedules of a whole group of nodes, efficient group-based discovery selectively recommends nodes that are most likely to be neighbors, in which the probability is calculated based on the nodes’ relative distance. Moreover, the sequence of received signal strengths are employed to estimate the relative distance for avoiding the effect of the node distribution. Extensive simulations are conducted to verify the effectiveness of the design. The results indicate that efficient group-based discovery statistically achieves a good trade-off between energy cost and discovery latency. Efficient group-based discovery also shows one order of magnitude reduction in discovery delay with a maximum of 6.5% increase in energy consumption compared with typical discovery methods.
Highlights
Wireless sensor networks (WSNs) are promising technologies that can be widely applied to many fields,[1] such as emergency rescue, biological detection, environmental measurement, and real-time monitoring.[2]
Facing the requirements mentioned above, we propose a relative distance based on group discovery scheme for leveraging the schedule reference mechanism such that the speed of neighbor discovery can be accelerated
We propose the efficient group-based discovery (EGD) based on relative distance, which can reduce discovery delay with small overhead
Summary
Wireless sensor networks (WSNs) are promising technologies that can be widely applied to many fields,[1] such as emergency rescue, biological detection, environmental measurement, and real-time monitoring.[2] Due to the energy constraints of nodes, the low duty-cycle mechanism is often adopted in WSNs, which saves the energy by listening briefly and shutting down radio most of the time. Such a mechanism makes it difficult for nodes to discover their neighbors because nodes have to listen the channel in an asynchronous manner. Neighbor discovery in low duty-cycle WSNs has attracted extensive research attention In such networks, each node periodically wakes up and sleeps. The main design and theoretical analysis are described in section ‘‘System design.’’ The simulation results are presented in section ‘‘Evaluation.’’ section ‘‘Conclusion’’ concludes the whole article
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