MODEL-BASED ASSESSMENT OF ENERGY AND RELIABILITY EFFICIENCY IN WIRELESS SENSOR NODES
Keywords:
WSN, energy efficiency, reliability, performance modeling, node lifetimeAbstract
Wireless sensor networks (WSN) are increasingly used in various control and management applications, where the efficiency of sensor nodes plays a decisive role in the overall operation of the network. This work presents a model-based assessment approach for assessing the energy efficiency and reliability of wireless sensor nodes. The proposed models analyze the relationship between transmission energy, node operation time, and network reliability under various operating conditions. Simulation-based estimates show how energy constraints and packet loss levels affect the stable operation of sensor nodes. The study compares the effectiveness of several existing energy models and provides recommendations for optimizing the behavior of nodes in energy-restricted environments.
References
1. Y. Liu, K.-W. Chin, C. Yang, and T. He, “Nodes deployment for coverage in rechargeable wireless sensor networks” IEEE Trans. Veh. Technol., vol. 68, no. 6, pp. 6064–6073, Jun. 2019.
2. K. O. Ibrahim, G. M. Abdulsahib, and B. M. Sabbar, ‘‘Optimization of wireless sensor network coverage using the Bee algorithm’’ J. Inform. Sci. Eng., vol. 36, no. 2, pp. 377–386, May 2020
3. N. Temene, C. Sergiou, C. Georgiou, V. Vassiliou, A survey on mobility in Wireless Sensor Networks, Ad Hoc Netw. 125 (2022).
4. L. Sathish Kumar, S. Ahmad, S. Routray, A.V. Prabu, A. Alharbi, B. Alouffi, S. Rajasoundaran, Modern energy optimization approach for efficient data communication in IoT-based wireless sensor networks, Wirel. Commun. Mob. Comput. 2022 (2022) 1–13.
7. Nafisa Inoyatovna Juraeva, Alisher Fayzulla ugli Khayrullaev, Javlon Hoshim ugli Hamraev. Analysis of The Energy Efficiency of Wireless Communication When Receiving A Data Stream // IOP Conf. Series: Materials Science and Engineering 981 (2020) 032007.
8. A. F. Khayrullaev, "Remote Monitoring of Low Voltage Opl With Power Theft and Fault Detection Using Wsn," 2024 4th International Conference on Technological Advancements in Computational Sciences (ICTACS), Tashkent, Uzbekistan, 2024, pp. 1367-1372
9. F. Tsvetanov and I. Georgieva, "Modeling of Energy Consumption of Sensor Nodes," 2020 43rd International Convention on Information, Communication and Electronic Technology (MIPRO), Opatija, Croatia, 2020, pp. 431-436
10. M. Rohman, F. Baskoro, W. Aribowo, Y. S. Nugroho, A. P. Nurdiansyah and L. E. C. Ningrum, "Selection of the Modulation, Distance, and Number of Hop Nodes Parameters to Determine the Minimum Energy in the Wireless Sensor Network," 2022 Fifth International Conference on Vocational Education and Electrical Engineering (ICVEE), Surabaya, Indonesia, 2022, pp. 118-123.
11. A. A. Ahmed, Z. M. Hussein, A. H. Najim, K. M. Ali Alheeti, N. S. Mohd Satar and A. H. Abdallah Hashim, "Performance Analysis of Energy and Secure Efficient Routing for Wireless Sensor Networks," 2024 International Conference on Decision Aid Sciences and Applications (DASA), Manama, Bahrain, 2024, pp. 1-6.
12. P. Sushma, V. Vinay Kumar, A. M, J. Ravi, E. N. V. Purna Chandra Rao and V. Gokula Krishnan, "Enhancement of Energy Efficiency in WSN using Sustainable Energy Aware Multipath Routing Protocol for IoT Applications," 2025 International Conference on Computing Technologies & Data Communication (ICCTDC), HASSAN, India, 2025, pp. 1-5.
13. B. Kumar, A. R. Kumar and R. Kumar, "Fuzzy and Cluster Based Energy-Efficient Zonal Stable Routing Protocol for WSN-IoT Network," 2024 3rd Edition of IEEE Delhi Section Flagship Conference (DELCON), New Delhi, India, 2024, pp. 1-6
14. Khujamatov, H.; Davronbekov, D.; Khayrullaev, A.; Abdullaev, M.; Mukhiddinov, M.; Cho, J. ERIRMS Evaluation of the Reliability of IoT-Aided Remote Monitoring Systems of Low-Voltage Overhead Transmission Lines. Sensors 2024, 24, 5970.
15. O. Hassan, M. -E. Riffi and I. Mzili, "Metaheuristic Optimization for Energy Efficiency and Lifetime Extension in Wireless Sensor Networks: A Comprehensive Survey," 2025 International Conference on Artificial Intelligence, Computer, Data Sciences and Applications (ACDSA), Antalya, Turkiye, 2025, pp. 1-8
16. T. C. Jesus, D. G. Costa, P. Portugal, F. Vasques and A. Aguiar, "Modelling Coverage Failures Caused by Mobile Obstacles for the Selection of Faultless Visual Nodes in Wireless Sensor Networks," in IEEE Access, vol. 8, pp. 41537-41550, 2020.
17. R. W. Anwar, F. Outay, K. N. Qureshi, S. Iqbal and K. Z. Ghafoor, "State-Based Energy Calculation Scheme for Internet of Things Networks," in IEEE Access, vol. 11, pp. 106967-106979, 2023
18. A. Kumar, K. Singh, T. Khan, A. Ahmadian, M. H. M. Saad and M. Manjul, "ETAS: An Efficient Trust Assessment Scheme for BANs," in IEEE Access, vol. 9, pp. 83214-83233, 2021
19. K. N. Dattatraya and K. R. Rao, ‘‘Hybrid based cluster head selection for maximizing network lifetime and energy efficiency in WSN,’’ J. King Saud Univ. Comput. Inf. Sci., vol. 34, no. 3, pp. 716–726, Mar. 2022
20. Z. Wang, H. Xie, D. He, and S. Chan, ‘‘Wireless sensor network deployment optimization based on two flower pollination algorithms,’’ IEEE Access, vol. 7, pp. 180590–180608, 2019.
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