Abstract
In the recent past, a significant increase has been observed in the use of underwater wireless sensor networks for aquatic applications. However, underwater wireless sensor networks face several challenges including large propagation delays, high mobility, limited bandwidth, three-dimensional deployments, expensive manufacturing, and energy constraints. It is crucial for underwater wireless sensor networks to mitigate all these limitations primarily caused by the harsh underwater environment. To address some of the pertinent challenges, adaptive hop-by-hop cone vector-based forwarding routing protocol is proposed in this article which is based on the adaptive hop-by-hop vector-based forwarding. The novelty of adaptive hop-by-hop cone vector-based forwarding includes increasing the transmission reliability in sparse sensor regions by changing the base angle of the cone according to the network structure. The number of duplicate packets and end-to-end delay is also reduced because of the reduced base angle and a smart selection criterion for the potential forwarder node. The proposed routing protocol adaptively tunes the height and opening of the cone based on the network structure to effectively improve the performance of the network. Conclusively, this approach significantly reduces energy tax, end-to-end delay, and packet delivery ratio.
Highlights
Underwater wireless sensor networks (UWSNs) are a robust application of the wireless sensor networks (WSNs) that are mainly used for examining the oceanic environment
We address the issue of duplicate packet transmission in AHH-VBF by proposing a new protocol called adaptive hop-by-hop cone vector-based forwarding (AHHC-VBF), where we divide the hemispheric forwarding region into smaller portions
The packet delivery ratio (PDR) increases with the increase in the number of nodes in both protocols AHHC-VBF and AHH-VBF
Summary
Underwater wireless sensor networks (UWSNs) are a robust application of the wireless sensor networks (WSNs) that are mainly used for examining the oceanic environment. The communication means used for UWSNs are entirely different from the terrestrial WSNs. Radio frequencies cannot be used for signaling as they are significantly attenuated in water. Radio frequencies cannot be used for signaling as they are significantly attenuated in water These frequencies can still be utilized for the link between surface-deployed sinks and offshore station(s) as they offer attractive features like low bit error rate, reliability, and significant bandwidth. Despite the feasibility of the acoustic signal in the underwater environment, it faces intrinsic challenges that include low propagation speed (1500 m/s), multi-path fading, and high bit error rate varying at different depths
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