SOUNET: Self-Organized Underwater Wireless Sensor Network

Kim, Hee-won; Cho, Ho-Shin

doi:10.3390/s17020283

Cited by 19 publications

(11 citation statements)

References 33 publications

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“…In conclusion, our approach proves that CBCL and CDNM are better than NBCL, and at the same time, compared to some previous works ([ 19 ] (2011), [ 20 ] (2013), [ 21 ] (2014), [ 22 ] (2015), [ 26 ] (2016) and [ 27 ] (2017)), the SQPCM can be employed to evaluate the systematic performance of a network on coverage, connectivity durability and rapid-reactivity, as shown in Table 4 .…”

Section: Simulation Experimentssupporting

confidence: 73%

Cross Deployment Networking and Systematic Performance Analysis of Underwater Wireless Sensor Networks

Wei

Song

Yin

et al. 2017

Sensors

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Underwater wireless sensor networks (UWSNs) have become a new hot research area. However, due to the work dynamics and harsh ocean environment, how to obtain an UWSN with the best systematic performance while deploying as few sensor nodes as possible and setting up self-adaptive networking is an urgent problem that needs to be solved. Consequently, sensor deployment, networking, and performance calculation of UWSNs are challenging issues, hence the study in this paper centers on this topic and three relevant methods and models are put forward. Firstly, the normal body-centered cubic lattice to cross body-centered cubic lattice (CBCL) has been improved, and a deployment process and topology generation method are built. Then most importantly, a cross deployment networking method (CDNM) for UWSNs suitable for the underwater environment is proposed. Furthermore, a systematic quar-performance calculation model (SQPCM) is proposed from an integrated perspective, in which the systematic performance of a UWSN includes coverage, connectivity, durability and rapid-reactivity. Besides, measurement models are established based on the relationship between systematic performance and influencing parameters. Finally, the influencing parameters are divided into three types, namely, constraint parameters, device performance and networking parameters. Based on these, a networking parameters adjustment method (NPAM) for optimized systematic performance of UWSNs has been presented. The simulation results demonstrate that the approach proposed in this paper is feasible and efficient in networking and performance calculation of UWSNs.

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Section: Simulation Experimentssupporting

confidence: 73%

Cross Deployment Networking and Systematic Performance Analysis of Underwater Wireless Sensor Networks

Wei

Song

Yin

et al. 2017

Sensors

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“…Massachusetts Institute of Technology (MIT) has daknet [21], where buses or public service vehicles are used as DMC to provide Internet services in remote rural areas. In underwater wireless sensor network (UWSN), an autonomous underwater vehicle (AUV) is also used as a mobile node for message transmitting [22,23]. This research also developed a DTSN mobile node, the Inspection Robot [6,7] for constructing the grid monitoring system in remote areas.…”

Section: Application Of Delay Tolerant Sensor Network (Dtsn)mentioning

confidence: 99%

Robot Delay-Tolerant Sensor Network for Overhead Transmission Line Monitoring

Fan

Wang

et al. 2018

Applied Sciences

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The rapid development of the smart grid has led to higher maintenance cost and greater scalability of transmission lines. An effective and secure monitoring system for power lines has become a bottleneck restricting the intellectualization of power grids. To address this problem, a novel method is proposed for the intelligent monitoring of power grids (Robot Delay-Tolerant Sensor Network, RDTSN) based on an inspection robot, Wireless Sensor Network (WSN) and Delay-Tolerant Sensor Network (DTSN) to achieve low-cost, energy-efficient, elastic and remote monitoring of power grids. With RDTSN, a smart grid can detect the fault of transmission lines and evaluate the operational state of power grids. To build an effective monitoring system for a smart grid, this research focuses on designing a methodology that achieves efficient and secure delivery of the data inspected on transmission lines. Multiple RDTSN scenarios are performed, in which different routing algorithms are explored to determine the optimal parameters, with a balance in network performance and financial cost. Furthermore, a data delivery strategy is introduced to ensure communication security.

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“…We assume that all nodes, which are equivalent in terms of capability and physical specification, are fixed on the seabed without timing synchronization and that they acquire propagation delay information from/to one-hop-distance neighbors through network initialization [ 35 ]. In addition, the nodes configure a distributed and partially connected mesh topology where they are connected to their one-hop distance neighbors.…”

Section: System Descriptionmentioning

confidence: 99%

UCMAC: A Cooperative MAC Protocol for Underwater Wireless Sensor Networks

Kim

Cho

2018

Sensors

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This paper proposes a cooperative medium access control (MAC) protocol for underwater wireless sensor networks (UWSNs) named UCMAC, which fundamentally benefits from cooperative communication. In UCMAC, a source identifies cooperators and provides its destination with a list of the cooperators while also delineating their proximity to the destination. For erroneous reception of data packets, the destination then requests retransmission to the cooperators in a closest-one-first manner. A designated cooperator transmits the buffered data packet it has successfully overheard from the source or other cooperators. A signaling procedure and the various waiting times of the nodes are carefully designed to address the overheads that stem from cooperation. Through computer simulation, this paper evaluates UCMAC in terms of system throughput, latency, single-hop packet delivery ratio (PDR), and energy efficiency. The results show that UCMAC performs better than existing schemes, including MACA-U and CD-MACA.

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SOUNET: Self-Organized Underwater Wireless Sensor Network

Cited by 19 publications

References 33 publications

Cross Deployment Networking and Systematic Performance Analysis of Underwater Wireless Sensor Networks

Cross Deployment Networking and Systematic Performance Analysis of Underwater Wireless Sensor Networks

Robot Delay-Tolerant Sensor Network for Overhead Transmission Line Monitoring

UCMAC: A Cooperative MAC Protocol for Underwater Wireless Sensor Networks

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