Volume 16 , Issue 1 , PP: 233-243, 2024 | Cite this article as | XML | Html | PDF | Full Length Article
R. Padmaraj 1 * , K. Selvakumar 2
Doi: https://doi.org/10.54216/FPA.160116
Wireless sensor network (WSN) was utilized widely in numerous areas owing to their accessibility in data collection, processing, and transmission, and the strength and reliability of data processing and transmission are based on the accuracy of the positions of sensor nodes (SNs) in the WSN. Sink node location estimation in WSN is a vital task intended to define the geographical position of the sink node in the network area of coverage. This procedure normally includes using numerous localization techniques that trust data like received signal strength, arrival time, time variance of arrival, or angle of arrival from adjacent SNs. The accuracy of sink node localization directly influences the efficiency of data aggregation, routing procedures, and complete performance of the network in tasks like environmental monitoring, target tracking, and event recognition. As WSNs are frequently used in remote environments where physical involvement is unusable, an effective and accurate sink node localization model plays a vital part in certifying the network's longevity and reliability. This study develops an Efficient Sink Node Position Estimation using the Harris Hawks Optimization (SNPE-HHO) Algorithm in WSN. The main intention of the SNPE-HHO technique is to recognize the optimal position of the sink node in the network. To achieve this, the SNPE-HHO technique employs the HHO system which gets inspiration from the hunting tactics of Harris Hawk. Moreover, the SNPE-HHO technique computes a fitness function that can drive the searching direction of the HHO algorithm and enhance the node estimation performance. The performance analysis of the SNPE-HHO method is verified by utilizing distinct metrics. The experimentation values confirmed the improved estimation performance of the SNPE-HHO technique over other existing methods
Internet of Things , Wireless Sensor Network , Harris Hawks Optimization , Sink Node , Fitness Function
[1] H. Wang, L. Shao, M. Li, B. Wang, P. Wang, Estimation of clock skew for time synchronization based on two-way message exchange mechanism in industrial wireless sensor networks, IEEE Trans. Ind. Inf. 6 (2017) 1–10.
[2] Naranjo, F.V., Vivar, S.M., Arias, E.J. and Atassi, R., 2023. Early Energy Consumption Prediction as a Key Element in Smart City Sustainability. Journal of Intelligent Systems and Internet of Things, 11(1), pp.12-2.
[3] V. Bhanumathi, K. Kalaivanan, The role of geospatial technology with IoT for precision agriculture, in: Das H., Barik R., Dubey H., Roy D. (Eds.), Cloud Computing for Geospatial Big Data Analytics. Studies in Big Data, Vol. 49, Springer, Cham, 2019, pp. 225–250.
[4] Marcelo Y. Villacis, Oswaldo T. Merlo, Diego P. Rivero, S. K. Towfek. "Optimizing Sustainable Inventory Management using An Improved Big Data Analytics Approach." Journal of Intelligent Systems and Internet of Things, Vol. 11, No. 1, 2024 ,PP. 55-64.
[5] Ruiz, D.P., Vasquez, R.A.D. and Jadan, B.V., 2023. Predictive Energy Management in Internet of Things: Optimization of Smart Buildings for Energy Efficiency. Journal of Intelligent Systems and Internet of Things, 10(2), pp.08-8.
[6] K. Kalaivanan, V. Bhanumathi, Reliable location aware and Cluster-Tap Root based data collection protocol for large scale wireless sensor networks, J. Netw. Comput. Appl. 118 (2018) 83–101.
[7] Afotey, B. and Lovely-Quao, C., 2023. Ambient air pollution monitoring and health studies using low-cost Internet-of-things (IoT) monitor within KNUST Community. Journal of Intelligent Systems and Internet of Things, 10(2), pp.49-9
[8] V. Bhanumathi, K. Kalaivanan, Application specific sensor-cloud: Architectural model, in: Mishra B., Dehuri S., Panigrahi B., Nayak A., Mishra B., Das H. (Eds.), Computational Intelligence in Sensor Networks. Studies in Computational Intelligence, Vol. 776, Springer, Berlin, Heidelberg, 2019, pp. 277–306.
[9] Y. Lu, Industry 4.0: A survey on technologies, applications and open research issues, J. Ind. Inf. Integr. 6 (2017) 1–10.
[10] I. Al-Anbagi, M. Erol-Kantarci, H.T. Mouftah, A survey on cross-layer quality of service approaches in WSNs for delay and reliability-aware applications, IEEE Commun. Surv. Tutor. 18 (1) (2016) 525–552.
[11] Rayavarapu, V.C.S.R. and Mahapatro, A., 2024. MOANS DV-Hop: An anchor node subset based localization algorithm for wireless sensor networks. Ad Hoc Networks, 152, p.103323.
[12] Soundararajan, S., Kurangi, C., Basha, A., Uthayakumar, J., Kalaivani, K., Dhamodaran, M. and Shukla, N.K., 2023. Metaheuristic optimization based node localization and multihop routing scheme with mobile sink for wireless sensor networks. Wireless Personal Communications, 129(4), pp.2583-2605
[13] Gantassi, R., Messous, S., Masood, Z., Sias, Q.A. and Choi, Y., 2024. Enhanced Network QoS in Large Scale and High Sensor Node Density Wireless Sensor Networks Using (IR-DV-Hop) localization algorithm and mobile data collector (MDC). IEEE Access.
[14] Amutha, J., Sharma, S. and Sharma, S.K., 2022. An energy efficient cluster based hybrid optimization algorithm with static sink and mobile sink node for Wireless Sensor Networks. Expert Systems with Applications, 203, p.117334.
[15] Gupta, A.D. and Kumar Rout, R., 2024. SMEOR: Sink mobility‐based energy‐optimized routing in energy harvesting‐enabled wireless sensor network. International Journal of Communication Systems, 37(4), p.e5679.
[16] Gupta, D., Wadhwa, S., Rani, S., Khan, Z. and Boulila, W., 2023. EEDC: An Energy Efficient Data Communication Scheme Based on New Routing Approach in Wireless Sensor Networks for Future IoT Applications. Sensors, 23(21), p.8839
[17] Zaarour, N., Hakem, N. and Kandil, N., 2024. An Accurate Anchor-Free Contextual Received Signal Strength Approach Localization in a Wireless Sensor Network. Sensors, 24(4), p.1210.
[18] Karunanithy, K. and Velusamy, B., 2021. Directional antenna based node localization and reliable data collection mechanism using local sink for wireless sensor networks. Journal of Industrial Information Integration, 24, p.100222.
[19] Lahmar, I., Zaier, A., Yahia, M., Lloret, J. and Bouallegue, R., 2023. Optimal data transmission for decentralized IoT and WSN based on Type-2 Fuzzy Harris Hawks Optimization. Internet of Things, p.101028.
[20] Yu, S., Zhu, J. and Lv, C., 2023. A quantum annealing bat algorithm for node localization in wireless sensor networks. Sensors, 23(2), p.782.