Browse > Article
http://dx.doi.org/10.15207/JKCS.2018.9.9.047

Robust Acknowledgement Transmission for Long Range Internet of Things  

Lee, Il-Gu (Department of Convergence Security Engineering, Sungshin University)
Publication Information
Journal of the Korea Convergence Society / v.9, no.9, 2018 , pp. 47-52 More about this Journal
Abstract
Wi-Fi enabled Internet of Things (IoTs) had a substantial impact on society, economy and industry. However wireless connectivity technologies in unlicensed band such as Wi-Fi are vulnerable to interferences. They also face difficulty providing wireless connectivity over long range in dense networks due to the dynamically changed interference effect and asymmetric interference conditions. In this paper, robust acknowledgement transmission scheme is proposed for long range IoTs. According to the proposed scheme, it is possible to control the transmission rate of the transmission success rate of the response frame by adjusting the transmission rate of the response frame when the interference is present asymmetrically. It is also possible to use higher data rate when high quality link is guaranteed. The evaluation results demonstrated the proposed scheme improves the aggregate throughput by at most 9 Mbps when 20 MHz bandwidth transmission mode was adopted.
Keywords
Asymmetric Interference; Dense Network; Internet of Things; Long Range; Wirless Network; Acknowledgement;
Citations & Related Records
Times Cited By KSCI : 3  (Citation Analysis)
연도 인용수 순위
1 H. Al-Tous, I. Barhumi, N. Al-Dhahir. (2017). Narrow-Band Interference Mitigation Using Compressive Sensing for AF-OFDM Systems. IEEE Transactions on Vehicular Technology, 66(7), 6146-6159.   DOI
2 S. Y. Kim, Y. J. Kim, H. K. Song. (2017). Adaptive cooperative transmission with spatial phase coding for interference mitigation in the wireless cellular communication. IEICE Transaction on Fundamentals of Electronics, Communications and Computer Sciences, 100(1), 317-321.
3 ANSI/IEEE Std 802.11, LAN/MAN Standards Committee of the IEEE Computer Society Std. (1999). Wireless LAN Medium Access Control (MAC) and Physical LAyer (PHY) specifications.
4 ANSI/IEEE Std 802.11e, LAN/MAN Standards Committee of the IEEE Computer Society Std. (2005). Wireless LAN Medium Access Control (MAC) and Physical Layer (PHY) Specifications. Amedment 7: Medium Access Control (MAC) Quality of Service (QoS).
5 M. S. Afaqui, E. G. Vilegas, E. L. Aguilera. (2016). IEEE 802.11ax: Challenges and requirements for future high efficiency WiFi. IEEE Wireless Communications, 99, 2-9.
6 I. Selinis, K. Katsaros, S. Vahid, R. Tafazolli. (2017). Exploiting the Capture Effect on DSC and BSS Color in Dense IEEE 802.11ax Deployments. In ACM Proceedings of the Workshop on ns-3, 47-54.
7 S. Parthasarathy, S. Kumar, R. K. Ganti, S. Kalyani, K. Giridhar. (2018). Error Vector Magnitude Analysis in Generalized Fading With Co-Channel Interference. IEEE Transactions on Communications, 66(1), 345-354.   DOI
8 I. G. Lee, M. Kim. (2016). Interference-aware self-optimizing Wi-Fi for high efficiency internet of things in dense networks. Computer Communications, 89, 60-74.
9 M. Chen, Y. Miao, Y. Hao, K. Hwang. (2017). Narrow band internet of things. IEEE Access, 5, 20557-20577.   DOI
10 D. E. Culler. (2017). The once and future Internet of everything. GetMobile: Mobile Computing and Communications, 20(3), 5-11.
11 I. Yaqoob, E. Ahmed, I. A. T. Hashem, A. I. A. Ahmed, A. Gani, M. Imran, M. Guizani. (2017). Internet of Things architecture: Recent advances, taxonomy, requirements, and open challenges. IEEE wirelress communications, 24(3), 10-16.
12 J. G. Hester, J. Kimionis, M. M. Tentzeris. (2017). Printed Motes for IoT Wireless Networks: State of the Art, Challenges, and Outlooks. IEEE Transactions on Microwave Theory and Techniques, 65(5), 1819-1830.   DOI
13 B. Vejlgaard, M. Lauridsen, H. Nguyen, I. Z. Kovacs, P. Mogensen, M. Sorensen. (2017). Interference impact on coverage and capacity for low power wide area IoT networks. In IEEE Wireless Communications and Networking Conference (WCNC), 1-6.
14 C. D. Lee. (2017). An Adaptive Traffic Interference Control System for Wireless Home IoT Services. Journal of Digital Convergence, 15(4), 259-266.   DOI
15 D. C. Son. (2016). A Study on Algorithm for Reducing Communication Error Rate in Special Network. Journal of Digital Convergence, 14(11), 325-331.   DOI
16 J. H. Kim, J. H. Cho, D. J. Cho, D. C. Son. (2017). Journal of Convergence for Information Technology, 7(5), 117-122.   DOI
17 G. Manzi, M. Felizianim P. A. Beeckman, N. van Dijk. (2009). Coexistence between ultra-wideband radio and narrow-band wireless LAN communication systems - Part II: EMI evaluation. IEEE Transaction on Electromagnetic Compatibility, 51(2), 382-390.   DOI
18 S. Vitturi, L. Seno, F. Tramarin, M. Bertocco. (2013). On the rate adaptation techniques of IEEE 802.11 networks for industrial applications. IEEE Transactions on Industrial Informatics, 9(1), 198-208.   DOI
19 T. Aittomaki, V. Koivunen. (2017). Mismatched filter design and interference mitigation for MIMO radars. IEEE Transactions on Signal Processing, 65(2), 454-466.   DOI