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Guest Editorial Special Issue on Internet of Things for Smart Ocean
2020
IEEE Internet of Things Journal
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The article "Dynamic magnetic induction wireless communications for autonomous-underwater-vehicle-assisted underwater IoT" by Wei et al. proposes low-power magnetic induction (MI)-based wireless communications ...
In the article "Localization and tracking control using hybrid acoustic-optical communication for autonomous underwater vehicles," Zhang et al. studied the problem of localization and tracking of a mobile ...
doi:10.1109/jiot.2020.3020444
fatcat:delnh2fehzczffi5vqh6nblmaq
Table of contents
2020
IEEE Internet of Things Journal
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Guan
9819
Dynamic Magnetic Induction Wireless Communications for Autonomous-Underwater-Vehicle-Assisted Underwater
IoT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .D. ...
Alouini 10038 Localization and Tracking Control Using Hybrid Acoustic-Optical Communication for Autonomous Underwater Vehicles . . . . . . . . . . . . . . D. Zhang, I. N'Doye, T. Ballal, T. Y. ...
doi:10.1109/jiot.2020.3024417
fatcat:2joyhgarkvfphfu324cztj2czq
Reconfigurable Intelligent Surfaces in Challenging Environments: Underwater, Underground, Industrial and Disaster
[article]
2021
arXiv
pre-print
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2020 pre-print arXiv:2011.12110v1 fatcat:2oexxqug6jdrtn2kesj5xnprz4Other Versions
Surprisingly, the benefits of RIS for wireless networking in underwater and underground medium as well as in industrial and disaster environments have not been addressed yet. ...
In this paper, we aim at filling this gap by discussing potential use cases, deployment strategies and design aspects for RIS devices in underwater IoT, underground IoT as well as Industry 4.0 and emergency ...
Here, the weak absorption of light can be exploited in order to guide the signal to the destination with a very little path loss.
2) Magnetic induction/resonance Magnetic induction (MI) or magnetic resonance ...
arXiv:2011.12110v2
fatcat:n5rhnwhvuvbvxd5blsb55b7xfq
Federated Learning for IoUT: Concepts, Applications, Challenges and Opportunities
[article]
2022
arXiv
pre-print
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Internet of Underwater Things (IoUT) have gained rapid momentum over the past decade with applications spanning from environmental monitoring and exploration, defence applications, etc. ...
There are primarily four underwater wireless communication methods namely -Under water Acoustic Communication (UAC), radio communication, wireless optical communication and magnetic -inductive communication ...
Internet of Underwater Things IoUT enable several autonomous vehicles in underwater to collaborate and communicate with each other. ...
arXiv:2207.13976v1
fatcat:3ttovdqujzaypiaicctkgsypwm
2020 Index IEEE Internet of Things Journal Vol. 7
2020
IEEE Internet of Things Journal
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., Rateless-Code-Based Secure Cooperative Transmission Scheme for Industrial IoT; JIoT July 2020 6550-6565 Jamalipour, A., see Murali, S., JIoT Jan. 2020 379-388 James, L.A., see Wanasinghe, T.R., ...
., +, JIoT Oct. 2020 9728-9746
Dynamic Magnetic Induction Wireless Communications for Autono-
mous-Underwater-Vehicle-Assisted Underwater IoT. ...
., +, JIoT April 2020 2531-2538
Electromagnetic induction
Dynamic Magnetic Induction Wireless Communications for Autono-
mous-Underwater-Vehicle-Assisted Underwater IoT. ...
doi:10.1109/jiot.2020.3046055
fatcat:wpyblbhkrbcyxpnajhiz5pj74a
Underwater Wireless Sensor Networks: A survey on enabling technologies, localization protocols, and Internet of Underwater Things
2019
IEEE Access
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INDEX TERMS Underwater wireless sensor networks, underwater wireless communications, magneto-inductive communications, acoustic communications, simultaneous wireless power, information transfer, Internet ...
Mobile nodes as Unmanned Underwater Vehicle (UUV) or Autonomous Underwater Vehicle (AUV) are required from wide-range UWSN to cover void region. ...
MAGNETO-INDUCTIVE COMMUNICATIONS
Magnetic Induction (MI) is mostly used for Underground Wireless Communication Networks (UGWN) [94]-[98] where the air is no longer the propagation medium but rock, soil ...
doi:10.1109/access.2019.2928876
fatcat:pdkz3t3lzfdzfplk5muyjbjeiy
Recent Advances, Future Trends, Applications and Challenges of Internet of Underwater Things (IoUT): A Comprehensive Review
2023
Journal of Marine Science and Engineering
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The IoUT framework integrates different underwater communication techniques such as optical, magnetic induction, and acoustic signals. ...
Underwater wireless communication (UWC) has widespread applications, including real-time aquatic data collection, naval surveillance, natural disaster prevention, archaeological expeditions, oil and gas ...
It is a smart network of underwater objects such as sensor nodes, cluster heads, cameras, autonomous underwater vehicles (AUVs), remotely operated vehicles (ROVs), autonomous surface vehicles (ASVs), buoys ...
doi:10.3390/jmse11010124
fatcat:mlicxpjaovfpvmbrohql37ox5m
A Review of Unmanned System Technologies with Its Application to Aquaculture Farm Monitoring and Management
2022
Drones
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capable of underwater and in-air wireless connectivity. ...
For offshore fish cages, there is a difficulty and risk in the continuous monitoring considering the presence of waves, water currents, and other underwater environmental factors. ...
Autonomous Underwater Vehicles (AUVs) Autonomous underwater vehicles (AUVs) or remotely operated underwater vehicles (ROV) are waterproof and submersible in the water as they are equipped with cameras ...
doi:10.3390/drones6010012
fatcat:aik6rkmbffcfvjuzeaeuwefzti
2020 Index IEEE Transactions on Vehicular Technology Vol. 69
2020
IEEE Transactions on Vehicular Technology
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Wireless Powered Spatial Crowdsourcing Networks; TVT Jan. 2020 920-934 Jibrin, R., see Jia, Y., TVT Dec. 2020 14173-14187 Jin, B., see Zhu, Y., TVT Aug. 2020 8317-8328 Jin, D., see ...
see Gholami, R., TVT Sept. 2020 9938-9950 Hoki, K., see Kawakami, T., TVT Dec. 2020 16168-16172 Hong, C., Shan, H., Song, M., Zhuang, W., Xiang, Z., Wu, Y., and Yu, X., A Joint Design of Platoon Communication ...
., +, TVT Dec. 2020 14458-14469 Optimal Time-Consuming Path Planning for Autonomous Underwater Vehicles Based on a Dynamic Neural Network Model in Ocean Current Environments. ...
doi:10.1109/tvt.2021.3055470
fatcat:536l4pgnufhixneoa3a3dibdma
Table of Contents
2021
IEEE Transactions on Vehicular Technology
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Li 263 A Hybrid Modular Cascade Machines System for Electric Vehicles Using Induction Machine and Permanent Magnet Synchronous Machine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ...
Zhang 331 3D Vehicle Detection With RSU LiDAR for Autonomous Mine . . . . . . . . . . . . . . . . . . . G. Wang, J. Wu, T. Xu, and B. ...
doi:10.1109/tvt.2021.3053948
fatcat:cwyk64fuyfgflh33nb24vux7ra
2021 Index IEEE Transactions on Vehicular Technology Vol. 70
2021
IEEE Transactions on Vehicular Technology
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The Author Index contains the primary entry for each item, listed under the first author's name. ...
., +, TVT Dec. 2021 12888-12901 Energy exchange Joint Design of Communication, Wireless Energy Transfer, and Control for Swarm Autonomous Underwater Vehicles. ...
., +, TVT July 2021 7243-7248 Optical wavelength conversion Joint Design of Communication, Wireless Energy Transfer, and Control for Swarm Autonomous Underwater Vehicles. ...
doi:10.1109/tvt.2022.3151213
fatcat:vzuzqu54irebpibzp3ykgy5nca
2020 Index IEEE Systems Journal Vol. 14
2020
IEEE Systems Journal
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., +, JSYST June 2020 2925-2936
Autonomous underwater vehicles
Neuroadaptive Sliding Mode Formation Control of Autonomous Under-
water Vehicles With Uncertain Dynamics. ...
Kumar, N., +, JSYST March 2020 909-915 Neuroadaptive Sliding Mode Formation Control of Autonomous Underwater Vehicles With Uncertain Dynamics. ...
., +, 2585 -2588 Energy-Efficient IoT-Fog-Cloud Architectural Paradigm for Real-Time Wildfire Prediction and Forecasting. 2003 -2011 Agent Pseudonymous Authentication-Based Conditional Privacy Preservation ...
doi:10.1109/jsyst.2021.3054547
fatcat:zf2aafvnfzbeje32qei5563myu
2019 Index IEEE Transactions on Industrial Informatics Vol. 15
2019
IEEE Transactions on Industrial Informatics
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., +, TII Sept. 2019 5235-5243
Autonomous underwater vehicles
An Architecture for Using Autonomous Underwater Vehicles in Wireless
Sensor Networks for Underwater Pipeline Monitoring. ...
., +, TII June 2019 3289-3299 An Architecture for Using Autonomous Underwater Vehicles in Wireless Sensor Networks for Underwater Pipeline Monitoring. ...
doi:10.1109/tii.2020.2968165
fatcat:utk3ywxc6zgbdbfsys5f4otv7u
A Hierarchical Information Acquisition System for AUV Assisted Internet of Underwater Things
2020
IEEE Access
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To tackle these issues, this paper proposes an autonomous underwater vehicle (AUV) assisted hierarchical information acquisition system composed of a marine stationary sensor layer and an AUV motion layer ...
As a typical model, an autonomous underwater vehicle (AUV) sails to visit anchored sensor nodes and establishs a short-range stable communication link, finally offloads the retrieved information back to ...
doi:10.1109/access.2020.3026395
fatcat:gs44pztsovh7nfbqczqpug4wci
Distributed Learning for Dynamic Channel Access in Underwater Sensor Networks
2020
Entropy
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In this study, the problem of dynamic channel access in distributed underwater acoustic sensor networks (UASNs) is considered. ...
First, we formulate the dynamic channel access problem in UASNs as a multi-agent Markov decision process, wherein each underwater sensor is considered an agent whose objective is to maximize the total ...
of several hundred meters unlike radio frequency, optical, or magnetic induction-based communication techniques. ...
doi:10.3390/e22090992
pmid:33286761
fatcat:ribahurys5hgrl3cufyo7uhuny
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