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22-04-2021

Void Hole Avoidance Based on Sink Mobility and Adaptive Two Hop Vector-Based Forwarding in Underwater Wireless Sensor Networks

Authors: Zia Ur Rehman, Arshad Iqbal, Bailin Yang, Tariq Hussain

Published in: Wireless Personal Communications | Issue 2/2021

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Abstract

Underwater Wireless Sensor Network (UWSN) accomplishes the consideration of a few scientists and academicians towards itself. Because of the brutality of the climate lies submerged represents various difficulties, i.e., high transmission delay, outstanding piece mistake rate, more expense in usage, sinks development and energy imperatives, unequal surface highlights of an area and low data transfer capacity, and so forth Void opening evasion is compulsory for to motivation behind limiting the utilization of energy and amplifying throughput and region inclusion. In this exploration work, the creator planned plans for void opening shirking initial one is, Avoiding Void Hole Adaptive Hop by Hop Vector-Based Forwarding (AVH-AHH-VBF) in submerged remote sensor organization and a second plan for limiting utilization of energy and expanding the lifetime of the organization, Sink Mobility-Adaptive Hop by Hop Vector-Based Forwarding (SM-AHH-VBF). Reproduction results show that our plans beat contrasted and standard arrangement as far as normal Packet Delivery Ratio (PDR), energy charge. Our reproduction confirms the effectiveness of our proposed procedure AVH-AHH-VBF equivalents to 0.17 and SM-AHH-VBF equivalents to 0.24 regarding normal PDR, AVH-AHH-VBF equivalents to 24j and SM-AHH-VBF equivalents to 5j for the normal energy charge, AVH-AHH-VBF had a tradeoff of 63% in light of considering two jumps and SM-AHH-VBF approaches 20% tradeoff for normal start to finish.

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Yisa, A. G., Dargahi, T., Belguith, S., & Hammoudeh, M. (2020). Security challenges of internet of underwater things: A systematic literature review. Transactions on Emerging Telecommunications Technologies, 32, e4203

Yan, L., He, Y., & Huangfu, Z. (2021). An uneven node self-deployment optimization algorithm for maximized coverage and energy balance in underwater wireless sensor networks. Sensors, 21, 1368CrossRef

Gupta, O., & Goyal, N. (2021). The evolution of data gathering static and mobility models in underwater wireless sensor networks: A survey. Journal of Ambient Intelligence and Humanized Computing, 12, 1–17.

Kheirabadi, M. T., & Mohamad, M. M. (2013). Greedy routing in underwater acoustic sensor networks: A survey. International Journal of Distributed Sensor Networks, 9, 701834CrossRef

Al-Bzoor, M., Al-assem, E., Alawneh, L., & Jararweh, Y. (2021). Autonomous underwater vehicles support for enhanced performance in the Internet of underwater things. Transactions on Emerging Telecommunications Technologies, 32, e4225CrossRef

Coutinho, R. W., Boukerche, A., Vieira, L. F., & Loureiro, A. A. (2015). Geographic and opportunistic routing for underwater sensor networks. IEEE Transactions on Computers, 65, 548–561MathSciNetCrossRef

Coutinho, R. W., Boukerche, A., Vieira, L. F., Loureiro, A. A. (2014) GEDAR: geographic and opportunistic routing protocol with depth adjustment for mobile underwater sensor networks, In 2014 IEEE International Conference on communications (ICC), pp. 251-256.

Nazareth, P., & Chandavarkar, B. (2021). Void-Aware Routing Protocols for Underwater Communication Networks: A Survey. Evolutionary Computing and Mobile Sustainable Networks, 53, 747–760.CrossRef

Yu, S., Liu, S., & Jiang, P. (2016). A high-efficiency uneven cluster deployment algorithm based on network layered for event coverage in UWSNs. Sensors, 16, 2103CrossRef

10.

Hussain, T., Rehman, Z. U., Iqbal, A., Saeed, K., & Ali, I. (2020). Two hop verification for avoiding void hole in underwater wireless sensor network using SM-AHH-VBF and AVH-AHH-VBF routing protocols. Transactions on Emerging Telecommunications Technologies, 31, e3992CrossRef

11.

Jin, Z., Wang, X., & Liu, Z. (2016). Relay selection and optimization algorithm of power allocation based on channel delay for UWSN. International Journal of Future Generation Communication and Networking, 9, 103–112

12.

Bandyopadhyay, D., & Sen, J. (2011). Internet of things: Applications and challenges in technology and standardization. Wireless Personal Communications, 58, 49–69CrossRef

13.

Xiong, Z., Wang, H., Zhang, L., Fan, T., & Shen, J. (2020). A ring-based routing scheme for distributed energy resources management in IIoT. IEEE Access, 8, 167490–167503CrossRef

14.

Butt, S. A., Bakar, K. A., Javaid, N., Gharaei, N., Ishmanov, F., Afzal, M. K., et al. (2019). Exploiting layered multi-path routing protocols to avoid void hole regions for reliable data delivery and efficient energy management for IoT-enabled underwater WSNs. Sensors, 19, 510CrossRef

15.

Han, G., Wang, H., Ansere, J. A., Jiang, J., & Peng, Y. (2020). SSLP: A stratification-based source location privacy scheme in underwater acoustic sensor networks. IEEE Network, 34, 188–195CrossRef

16.

Gola, K. K., Gupta, B. (2021) Underwater acoustic sensor networks: An energy efficient and void avoidance routing based on grey wolf optimization algorithm. Arabian Journal for Science and Engineering, pp. 1–16.

17.

Awais, M., Javaid,N., Naseer, N., Imran, M. (2019) Exploiting energy efficient routing protocols for Void Hole Alleviation in IoT enabled Underwater WSN, In 2019 15th International Wireless Communications and Mobile Computing Conference (IWCMC), pp. 1797–1802.

18.

Nguyen, K.-V., Nguyen, C.-H., Le Nguyen, P., Van Do, T., & Chlamtac, I. (2021). Energy-efficient routing in the proximity of a complicated hole in wireless sensor networks. Wireless Networks, 27, 1–17.

19.

Yu, H., Yao, N., & Liu, J. (2015). An adaptive routing protocol in underwater sparse acoustic sensor networks. Ad Hoc Networks, 34, 121–143CrossRef

20.

Ahmed, S., Javaid, N., Ahmad, A., Ahmed, I., Durrani, M. Y., Ali, A., et al. (2016). SPARCO: stochastic performance analysis with reliability and cooperation for underwater wireless sensor networks. Journal of Sensors, 2016, 1–17

21.

Noh, Y., Lee, U., Lee, S., Wang, P., Vieira, L. F., Cui, J.-H., et al. (2015). Hydrocast: Pressure routing for underwater sensor networks. IEEE Transactions on Vehicular Technology, 65, 333–347CrossRef

22.

Osorio, D. P. M., Olivo, E. E. B., Alves, H., Santos Filho, J. C. S., & Latva-aho, M. (2016). An adaptive transmission scheme for amplify-and-forward relaying networks. IEEE Transactions on Communications, 65, 66–78CrossRef

23.

Abbas, M. Z., Bakar, K. A., Ayaz, M., Mohamed, M. H., & Tariq, M. (2017). Hop-by-Hop dynamic addressing based routing protocol for monitoring of long range underwater pipeline. KSII Transactions on Internet and Information Systems, 11, 1237–1253

24.

Rao, P. S., Jana, P. K., & Banka, H. (2017). A particle swarm optimization based energy efficient cluster head selection algorithm for wireless sensor networks. Wireless Networks, 23, 2005–2020CrossRef

25.

Sher, A., Khan, A., Javaid, N., Ahmed, S. H., Aalsalem, M. Y., & Khan, W. Z. (2018). Void hole avoidance for reliable data delivery in IoT enabled underwater wireless sensor networks. Sensors, 18, 3271CrossRef

26.

Yadav, S., & Kumar, V. (2017). Optimal clustering in underwater wireless sensor networks: Acoustic, EM and FSO communication compliant technique. IEEE Access, 5, 12761–12776CrossRef

27.

Shah, M., Wadud, Z., Sher, A., Ashraf, M., Khan, Z. A., & Javaid, N. (2018). Position adjustment–based location error–resilient geo-opportunistic routing for void hole avoidance in underwater sensor networks. Concurrency and Computation: Practice and Experience, 30, e4772CrossRef

28.

Javaid, N., Shah, M., Ahmad, A., Imran, M., Khan, M. I., & Vasilakos, A. V. (2016). An enhanced energy balanced data transmission protocol for underwater acoustic sensor networks. Sensors, 16, 487CrossRef

29.

Kumar Gola, K., Dhingra, M., & Gupta, B. (2020). Void hole avoidance routing algorithm for underwater sensor networks. IET Communications, 14, 3837–3844CrossRef

30.

Sher, A., Javaid, N., Azam, I., Ahmad, H., Abdul, W., Ghouzali, S., et al. (2017). Monitoring square and circular fields with sensors using energy-efficient cluster-based routing for underwater wireless sensor networks. International Journal of Distributed Sensor Networks, 13, 1550147717717189CrossRef

31.

Hussain, A., Hussain, T., Ali, I., & Khan, M. R. (2020). Impact of sparse and dense deployment of nodes under different propagation models in manets. ADCAIJ Advances in Distributed Computing and Artificial Intelligence Journal, 9, 61–84CrossRef

Title: Void Hole Avoidance Based on Sink Mobility and Adaptive Two Hop Vector-Based Forwarding in Underwater Wireless Sensor Networks
Authors: Zia Ur Rehman
Arshad Iqbal
Bailin Yang
Tariq Hussain
Publication date: 22-04-2021
Publisher: Springer US
Published in: Wireless Personal Communications / Issue 2/2021
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-021-08518-9

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