A Probabilistic and Highly Efficient Topology Control Algorithm for Underwater Cooperating AUV Networks

Li, Ning; Çürüklü, Baran; Bastos, Joaquim; Sucasas, Victor; Fernández, José Antonio Sánchez; Rodrı́guez, Jonathan

doi:10.3390/s17051022

Cited by 20 publications

(9 citation statements)

References 36 publications

(50 reference statements)

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“…The speed of acoustic medium is five magnitudes less when compared to that of the radio frequency; therefore, the magnitude of propagation delay occurs in underwater environment is five times higher when compared to terrestrial environment. High bit error rates and momentary losses of connectivity (shadow zones) could occur and the power of the the battery suffers shortage, especially batteries cannot be recharged frequently [9][10][11]. Different I-UWSN routing protocols are introduced to overcome these challenges by taking the advantages of underwater characteristics.…”

Section: Introductionmentioning

confidence: 99%

A Secure Communication in IoT Enabled Underwater and Wireless Sensor Network for Smart Cities

Ali

Irfan

Shaf

et al. 2020

Sensors

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Nowadays, there is a growing trend in smart cities. Therefore, the Internet of Things (IoT) enabled Underwater and Wireless Sensor Networks (I-UWSN) are mostly used for monitoring and exploring the environment with the help of smart technology, such as smart cities. The acoustic medium is used in underwater communication and radio frequency is mostly used for wireless sensor networks to make communication more reliable. Therefore, some challenging tasks still exist in I-UWSN, i.e., selection of multiple nodes’ reliable paths towards the sink nodes; and efficient topology of the network. In this research, the novel routing protocol, namely Time Based Reliable Link (TBRL), for dynamic topology is proposed to support smart city. TBRL works in three phases. In the first phase, it discovers the topology of each node in network area using a topology discovery algorithm. In the second phase, the reliability of each established link has been determined while using two nodes reliable model for a smart environment. This reliability model reduces the chances of horizontal and higher depth level communication between nodes and selects next reliable forwarders. In the third phase, all paths are examined and the most reliable path is selected to send data packets. TBRL is simulated with the help of a network simulator tool (NS-2 AquaSim). The TBRL is compared with other well known routing protocols, i.e., Depth Based Routing (DBR) and Reliable Energy-efficient Routing Protocol (R-ERP2R), to check the performance in terms of end to end delay, packet delivery ratio, and energy consumption of a network. Furthermore, the reliability of TBRL is compared with 2H-ACK and 3H-RM. The simulation results proved that TBRL performs approximately 15% better as compared to DBR and 10% better as compared to R-ERP2R in terms of aforementioned performance metrics.

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Section: Introductionmentioning

confidence: 99%

A Secure Communication in IoT Enabled Underwater and Wireless Sensor Network for Smart Cities

Ali

Irfan

Shaf

et al. 2020

Sensors

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“…The common topology control method is to set the sleep node [19]. In this paper, nodes distributed in water are divided into clusters, control nodes in the cluster are changed according to the residual energy of nodes, and the dormancy time of nodes is set in combination with the number of neighbors, so as to reduce network energy consumption and prolong network lifetime [20]. Based on the above background, this paper designs a cluster sleep-wake scheduling algorithm based on 3D topology control.…”

Section: Introductionmentioning

confidence: 99%

A Cluster Sleep-Wake Scheduling Algorithm Based on 3D Topology Control in Underwater Sensor Networks

Zhang

Wang

Han

et al. 2019

Sensors

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3D topology control in underwater sensor networks is of great significance to ensuring reliable and efficient operation of the network. In this paper, by analyzing the characteristics of an underwater sensor network, we take the cube as the basic unit to perform 3D partition of the monitoring area, define the 3D partition unit and basic cluster structure of the underwater sensor network, and arrange rotating temporary control nodes in the cluster. Then, a cluster sleep-wake scheduling algorithm is proposed that compares the remaining node energy. It selects the node with the largest remaining energy as the working node, and the remaining nodes complete the transition of dormancy and waiting states as long as they reach the preset dormancy time. The node state settings of this phase are completed by the temporary control node. Temporary control nodes selecting and sleep-wake scheduling are used in the algorithm through 3D topology control, which reduces energy consumption and guarantees maximum sensing coverage of the entire network and the connection rate of active nodes. Simulation results further verify the effectiveness of the proposed algorithm.

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“…With the advancement in technologies being used underwater, there has been massive increase in research activities related to underwater wireless sensor networks (UWSNs) by both academia and industry [1][2][3]. They are comprised of sensor nodes and sink(s) that are deployed on the seabed through ships.…”

Section: Introductionmentioning

confidence: 99%

Towards Efficient Sink Mobility in Underwater Wireless Sensor Networks

et al. 2018

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The unique characteristics of underwater environment such as long propagation delay, limited bandwidth, energy-constraint and non-uniform topology are big challenges in designing a routing protocol for underwater wireless sensor networks (UWSNs). In this paper, a novel routing scheme is proposed through which two mobile sinks are used for efficient collection of sensed data packets. Moreover, a new metric "Mobile Sink Utility Ratio (MUR)" is also introduced that helps in measuring the usage of mobile sink in the collection of data packets. The proposed scheme is rigorously evaluated and compared with current state-of-the-art routing protocols. The simulation of the proposed scheme shows promising results in terms of throughput, network lifetime, packet drop ratio and MUR.

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A Probabilistic and Highly Efficient Topology Control Algorithm for Underwater Cooperating AUV Networks

Cited by 20 publications

References 36 publications

A Secure Communication in IoT Enabled Underwater and Wireless Sensor Network for Smart Cities

A Secure Communication in IoT Enabled Underwater and Wireless Sensor Network for Smart Cities

A Cluster Sleep-Wake Scheduling Algorithm Based on 3D Topology Control in Underwater Sensor Networks

Towards Efficient Sink Mobility in Underwater Wireless Sensor Networks

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