Conceptual Modeling of Narrow Band Communication System for Interference Free Channel Allocation

Conceptual Modeling of Narrow Band Communication System for Interference Free Channel Allocation

© 2022 by IJETT Journal
Volume-70 Issue-7
Year of Publication : 2022
Authors : S. Vandana, T. Madhavi
DOI : 10.14445/22315381/IJETT-V70I7P234

How to Cite?

S. Vandana, T. Madhavi, "Conceptual Modeling of Narrow Band Communication System for Interference Free Channel Allocation" International Journal of Engineering Trends and Technology, vol. 70, no. 7, pp. 329-338, 2022. Crossref,

Channel bandwidth allocation plays a vital role in Narrow Band Communication. In COTS Based 802.11 systems, the bandwidth of > 20MHz was utilized because the number of noninterference channels used for data communication is less than 4. Acquiring one of the noninterference channels for data transfer will increase the waiting time of the node for data transfer, and the communication range will be less. Several commercial devices like Lora and Sigfox are available with fixed bandwidth, and building a communication network is not possible with these devices. So, a conceptual model was demonstrated using open source 802.11 modules by changing its firmware to 1 MHz bandwidth. The narrow bandwidth of the channel is enough when the communication data is very low. In this 1 MHz bandwidth, a total of 9 channels, each with 2.3KHz, is allocated, with a guard band of 123KHz between channels to make the communication interference-free. This model can still increase the number of channels in contrast to less than 4 noninterference channels in COTS-based systems by allocating lesser bandwidth to the guard band or utilizing more bandwidth in the available 20 MHz.The model's performance evaluation shows required data and packet delivery rate values.

Channel Bandwidth, COTS Based 802.11 system, Guard band, Narrowband Communication.

[1] Arslan, H., & Bottomley, G. E, “Channel estimation in narrowband wireless communication systems,” Wireless Communications and Mobile Computing, vol.1, no.2, pp. 201-219, 2001.
[2] Herlich, M., & von Tüllenburg, F, “Introduction to Narrowband Communication,” In Wireless Congress: Systems and Applications , pp. 1-15, 2018.
[3] Ganesh, M. S., Patnaik, B., & Karthik, M, “ Narrowband speech signal bandwidth extension for intelligible speech communication,” In 2017 IEEE International Conference on Intelligent Techniques in Control, Optimization and Signal Processing , no.INCOS) , IEEE, pp.1-5, 2017.
[4] Lassen, T, “ Long-range RF communication: Why narrowband is the de facto standard,” White Paper.
[5] Hu, J., Bian, D., Xie, Z., Li, Y., & Fan, L, “An approach for narrow band interference detection in satellite communication using morphological filter,” In International Conference on Information Technology and Management Innovation, Shenzhen, China, 2015.
[6] Mwakwata, C. B., Malik, H., Mahtab Alam, M., Le Moullec, Y., Parand, S., & Mumtaz, S, “ Narrowband Internet of Things , no.NBIoT): From physical , no.PHY) and media access control , no.MAC) layers perspectives,” Sensors, vol.19, no.11, pp.2613, 2019.
[7] Sastry, A, “Estimation of Bit Error Rates for Narrow-Band Digital Communication in the Presence of Atmospheric Radio Noise Bursts,” IEEE Transactions on Communication Technology, vol.19, no.5, pp.733-735, 1971.
[8] Samara, L., Gouissem, A., Abdellatif, A. A., Hamila, R., & Hasna, M. O. “On the performance of tactical communication interception using military full duplex radios,” In 2019 IEEE 30th Annual International Symposium on Personal, Indoor and Mobile Radio Communications , no.PIMRC, pp.1-6, 2019.
[9] Aamir, M., & Zaidi, M. A, “A buffer management scheme for packet queues in MANET,” Tsinghua Science and Technology, vol.18, no.6, pp. 543-553, 2013.
[10] Chakkor, S., Cheikh, E. A., Baghouri, M., & Hajraoui, A, “Comparative performance analysis of wireless communication protocols for intelligent sensors and their applications,” arXiv preprint arXiv:1409.6884,2014.
[11] Chiani, M., & Giorgetti, A, “Coexistence between UWB and narrowband wireless communication systems,” Proceedings of the IEEE, vol.97, no.2, pp. 231-254, 2009.
[12] Giorgetti, A., Chiani, M., & Win, M. Z, “The effect of narrowband interference on wideband wireless communication systems,” IEEE Transactions on Communications, vol. 53, no.12, pp. 2139-2149.
[13] Ratasuk, R., Mangalvedhe, N., Ghosh, A., & Vejlgaard, B, “Narrowband LTE-M system for M2M communication,” In 2014 IEEE 80th vehicular technology conference , no.VTC2014-Fall) , pp. 1-5 IEEE, 2014.
[14] Xu, J., Yao, J., Wang, L., Ming, Z., Wu, K., & Chen, L, “Narrowband internet of things: Evolutions, technologies, and open issues,’ IEEE Internet of Things Journal, vol.5, no.3, pp. 1449-1462, 2017.
[15] Chen, J., Hu, K., Wang, Q., Sun, Y., Shi, Z., & He, S, “Narrowband internet of things: Implementations and applications,” IEEE Internet of Things Journal,vol. 4, no.6, pp. 2309-2314, 2017.
[16] Sinha, D., Verma, A. K., & Kumar, S, “Software defined radio: Operation, challenges and possible solutions,” In 2016 10th International Conference on Intelligent Systems and Control , no.ISCO) , pp. 1-5, 2016.
[17] Ronnberg, S. K., Bollen, M. H., & Wahlberg, M, “Interaction between narrowband power-line communication and end-user equipment,” IEEE Transactions on Power Delivery, vol. 26, no.3, pp. 2034-2039, 2011.
[18] Chen, M., Miao, Y., Hao, Y., & Hwang, K , “Narrow band internet of things,” IEEE access, vol.5, pp.20557-20577, 2017.
[19] Zemrane, H., Baddi, Y., & Hasbi, “A Internet of things smart home ecosystem,” In Emerging Technologies for Connected Internet of Vehicles and Intelligent Transportation System Networks , Springer, Cham , pp. 101-125, 2020.
[20] Desai, R., & Patil, B. P, “ Analysis of routing protocols for Ad Hoc Networks. In 2014 International Conference on Circuits, Systems,” Communication and Information Technology Applications , no.CSCITA) , pp. 111-115, 2014.
[21] Shaji K.A.Theodore, K. Rajiv Gandhi, V. Palanisamy, "Privacy Preserving Lightweight Cryptography Scheme for Clustered Vehicular Adhoc Networks" International Journal of Engineering Trends and Technology, vol. 70, no. 7, pp. 24-31, 2022.
[22] Vinodray Thumar, Dr. Saurabh Shah, Dr. Vipul Vekariya, “Design and Implementation of IPFS Enabled Security Framework for Multimedia Data Files,” International Journal of Engineering Trends and Technology, vol.70, no.1, pp. 355-361, 2022.