Abstract
This paper proposes novel randomized gossip-consensus-based sync (RGCS) algorithms to realize efficient time calibration in dynamic wireless sensor networks (WSNs). First, the unreliable links are described by stochastic connections, reflecting the characteristic of changing connectivity gleaned from dynamic WSNs. Secondly, based on the mutual drift estimation, each pair of activated nodes fully adjusts clock rate and offset to achieve network-wide time synchronization by drawing upon the gossip consensus approach. The converge-to-max criterion is introduced to achieve a much faster convergence speed. The theoretical results on the probabilistic synchronization performance of the RGCS are presented. Thirdly, a Revised-RGCS is developed to counteract the negative impact of bounded delays, because the uncertain delays are always present in practice and would lead to a large deterioration of algorithm performances. Finally, extensive simulations are performed on the MATLAB and OMNeT++ platform for performance evaluation. Simulation results demonstrate that the proposed algorithms are not only efficient for synchronization issues required for dynamic topology changes but also give a better performance in terms of converging speed, collision rate, and the robustness of resisting delay, and outperform other existing protocols.
Highlights
Ad hoc wireless sensor networks (WSNs) without preexisting infrastructures are composed of autonomous sensors [1], and the sensors are a variety of low cost, low power, sensing devices, which work cooperatively through ad hoc wireless communications
In the Revised-randomized gossip-consensus-based sync (RGCS), the collision rate is 2.1%, because the timing messages are delivered to the Media Access Control (MAC) layer of the nodes with long delays which collides with the synchronization link (Sync-L) event at few instants
This paper presents a new randomized and energy-efficient time synchronization protocol called RGCS for dynamic WSNs with randomly changing connectivity
Summary
Ad hoc wireless sensor networks (WSNs) without preexisting infrastructures are composed of autonomous sensors [1], and the sensors are a variety of low cost, low power, sensing devices, which work cooperatively through ad hoc wireless communications. Under a more practical delay model, it is of great interest to study randomized gossip algorithm for achieving the generalized consensus timing protocol that has faster convergence speed and lower collision rate in dynamic WSNs. Motivated by these, this paper presents an innovative randomized and efficient timing protocol for dynamic WSNs, including the mutual drift estimation, clock rate and offset compensation. The key novelty of the contribution lies in a randomized algorithm for the extension of the generalized consensus-based timing protocol which implements probabilistic synchronization using randomized gossip-type interactions and updates To achieve this goal, for the first time, we design the idea of the randomized activation of the synchronization links based on the preprogrammed Poisson process to activate a pair of nodes, and use the gossipconsensus-based approach with the converge-to-max criterion to fully adjust the clock rate and offset of random pairwise nodes.
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