IJCNIS Vol. 16, No. 5, 8 Oct. 2024
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NAN, Path Loss, Shadowing, Smart Metering, Zigbee
A fundamental and vital aspect of Smart Metering infrastructure is the communication technologies and techniques associated with it, especially between the Smart Meters and the Data Concentrator Unit. Among many available communication technologies, ZigBee provides a low-cost, low-power, and easy-to-deploy network solution for a Smart Meter network. There exists limited literature that discusses ZigBee as a potential communication technology for long-range networks. Hence thorough analysis is demanded on the suitability of ZigBee for smart meter deployment under different types of environmental conditions, coverage ranges, and obstacles. This work evaluates the performance of an extended ZigBee module in outdoor as well as indoor conditions in the presence of different types of obstacles. Parameters are obtained for path loss exponent and the standard deviation of the Gaussian Random variable to validate the Log Normal Shadowing model for modeling long-range ZigBee communication. The impact of obstacles on path loss is also considered. The results show that the Log Normal Shadowing model is a good approximation for the behavior of ZigBee path loss. Accordingly, the suitability of ZigBee for a Smart Meter network spanned as a Neighborhood Area Network is also assessed based on the approximated model.
Sehan Samarakoon, Maheshi B Dissanayake, Kithsiri M Liyanage, Sudheera Navaratne, Chirantha Jayasinghe, Prabhath Illangakoon, "Path Loss Analysis of ZigBee for Smart Meter Network Deployment in NAN", International Journal of Computer Network and Information Security(IJCNIS), Vol.16, No.5, pp.86-97, 2024. DOI:10.5815/ijcnis.2024.05.07
[1]T. Gupta and R. Bhatia, "Communication technologies in smart grid at different network layers: An overview.," in International Conference on Intelligent Engineering and Management (ICIEM), 2020.
[2]F. Zhang, W. Jiang, Q. Lin and H. Wu, "ZigBee-based wireless sensor network for environment monitoring ZigBee," Sensors & Transducers, vol. 237(9/10), pp.144-149, 2019.
[3]D. Baimel, S. Tapuchi and N. Baimel, "Smart grid communication technologies," Journal of Power and Energy Engineering, vol. 4(08), pp.1, 2016.
[4]R. Das and J. Bera, "ZigBee based small-world home area networking for decentralized monitoring and control of smart appliances," in 5th International Conference on Smart Grid and Smart Cities (ICSGSC), 2021.
[5]M. Lisowski, R. Masnicki and J. Mindykowski, "PLC-enabled low voltage distribution network topology monitoring," IEEE Transactions on Smart Grid, vol. 10(6), pp.6436-6448, 2019.
[6]M. Khazaei, L. Stankovic and V. Stankovic, "Trends and challenges in smart metering analytics," in 2019 MTMI International Conference on Emerging Issues in Business, Technology and Applied Sciences. pp.111-117, 2019
[7]F. Abrahamsen, Y. Ai and M. Cheffena, "Communication technologies for smart grid: A comprehensive survey," Sensors, vol. 21(23), p. p.8087, 2021.
[8]I. Kuzminykh, A. Snihurov and A. Carlsson, "Testing of communication range in ZigBee technology," in 14th International Conference the Experience of Designing and Application of CAD Systems in Microelectronics (CADSM), 2017.
[9]D. Sucie, "A study of RF link and coverage in ZigBee," Scientific Bulletin of the” Petru Maior”University of Târgu Mureş, Vol.7 (XXIV), no.1, pp. 5-10, 2010.
[10]A. Payal, C. Rai and B. Reddy, "Experimental analysis of some radio propagation models for smart wireless sensor networks applications," in SAI Intelligent Systems Conference (IntelliSys), 2015.
[11]Z. Chen, X. Fu, Y. Kong and D. Han, "Study on path loss of ZigBee signal in electrical substation environment," in International Conference on Cyberspace Technology (CCT 2014), 2014.
[12]M. Liang, C. Li, J. Wang and L. Li, "Power Loss Analysis of Zigbee Propagation Models on the Landslide of Heifang platform," in 6th International Conference on Information Engineering for Mechanics and Materials, 2016.
[13]S. Kurt and B. Tavli, "Path-Loss Modeling for Wireless Sensor Networks: A review of models and comparative evaluations," IEEE Antennas and Propagation Magazine, vol. vol. 59, no. no 1, pp. 18-37, Feb. 2017.
[14]S. Choudhary and D. Dhaka, "Path loss prediction models for wireless communication channels and its comparative analysis," International Journal of Engineering, Management & Sciences, vol. 2(3), pp.38-43, March 2015.
[15]A. Okumbor and O. Okonwo, "Empirical model of cellular signal propagation loss for smart grid environment," International Journal of Smart Grid and Clean Energy, vol. 5(4), pp.272-279, 2016.
[16]S. L. Mohammed, "Distance Estimation Based on RSSI and Log-Normal Shadowing Models for ZigBee Wireless Sensor Network," Engineering and Technology Journal, vol. 34, no. 15A, pp. 2950-2959, 2016.
[17]C. Rizzo, F. Lera and J. Villaroel, "3-D fadings structure analysis in straight tunnels toward communication, localization, and navigation," IEEE Transactions on Antennas and Propagation, vol. 67(9), pp.6123-6137, 2019.