Uplink Small Packet Transmission Performance Improvements in Fourth-Generation Cellular Networks

Authors

  • Nattanicha Tamkuan นักศึกษา หลักสูตรวิศวกรรมศาสตรมหาบัณฑิต สาขาวิชาวิศวกรรมคอมพิวเตอร์ คณะวิศวกรรมศาสตร์ มหาวิทยาลัยขอนแก่น
  • Bhichate Chiewthanakul รองศาสตราจารย์ สาขาวิชาวิศวกรรมคอมพิวเตอร์ คณะวิศวกรรมศาสตร์ มหาวิทยาลัยขอนแก่น

Keywords:

Machine-to-machine, Delay, Internet of things

Abstract

This article presented a concept of machine-to-machine data transmission in the fourth-generation cellular networks. The purpose was to achieve performance in terms of high reliability, high channel utilization, and low delay for uplink small packet transmission. The system model assumed a fixed blocklength communication in conjunction with a hybrid automatic repeat request over a complex single input and single output (SISO) additive white Gaussian noise channel. In addition, the system applied a nonasymptotic maximum coding rate metric for short packets integrated with slotted-Aloha random access communication protocol. The results of the study showed that the nonasymptotic   maximum code rate metric allowed the uplink small packet transmission to achieve high reliability, and more efficient utilization of communication channels, but it resulted in a slightly higher delay compared to a capacity measurement metric.

References

Atzori L, Iera A, Morabito G. The internet of things: A survey. Computer networks. 2010;54(15):2787–2805.

SECTOR S, ITU O. Series y: Global information infrastructure, internet protocol aspects and next-generation networks next generation networks–frameworks and functional architecture models. International Telecommunication Union, Geneva, Switzerland, Recommendation ITU-T Y. 2012;2060.

Fadlullah ZM, Fouda MM, Kato N, Takeuchi A, Iwasaki N, Nozaki Y. Toward intelligent machine-to-machine communications in smart grid. IEEE Communications Magazine. 2011;49(4):60–65.

Doukas C, Maglogiannis I. Bringing IoT and cloud computing towards pervasive healthcare. In: 2012 Sixth International Conference on Innovative Mobile and Internet Services in Ubiquitous Computing. IEEE; 2012. p. 922–926.

Zhou J, Leppanen T, Harjula E, Ylianttila M, Ojala T, Yu C, et al. Cloudthings: A common architecture for integrating the internet of things with cloud computing. In: Proceedings of the 2013 IEEE 17th international conference on computer supported cooperative work in design (CSCWD). IEEE; 2013. p. 651–657.

Jover RP, Murynets I. Connection-less communication of IoT devices over LTE mobile networks. In: 2015 12th annual IEEE international conference on sensing, communication, and networking (SECON). IEEE; 2015. p. 247–255.

Cox C. An introduction to LTE: LTE, LTE-advanced, SAE and 4G mobile communications. John Wiley & Sons; 2012.

3GPP TR 25 913. Requirements for Evolved UTRA (E-UTRA) and Evolved UTRAN (EUTRAN); 2009.

Durisi G, Koch T, Popovski P. Toward massive, ultrareliable, and low-latency wireless communication with short packets. Proceedings of the IEEE. 2016;104(9):1711–1726.

Polyanskiy Y, Poor HV, Verdú S. Channel coding rate in the finite blocklength regime. IEEE Transactions on Information Theory. 2010;56(5):2307.

Tan VYF, Tomamichel M. The third-order term in the normal approximation for the AWGN channel. IEEE Transactions on Information Theory. 2015;61(5):2430–2438.

Ghavimi F, Chen HH. M2M communications in 3GPP LTE/LTE-A networks: Architectures, service requirements, challenges, and applications. IEEE Communications Surveys & Tutorials. 2014;17(2):525–549.

Östman J. Short-Packet Communications: Fundamental Performance and Key Enablers. 2019;.

ETSI T. 136 213, LTE; Evolved Universal Terrestrial Radio Access (E-UTRA); Physical layer procedures. Technical Report Version 11.2. 0 (2013); 2013.

Lozano A, Jindal N. Transmit diversity vs. spatial multiplexing in modern MIMO systems. IEEE Transactions on wireless communications. 2010;9(1):186–197.

Popovski P. Ultra-reliable communication in 5G wireless systems. In: 1st International Conference on 5G for Ubiquitous Connectivity. IEEE; 2014. p. 146–151.

Laner M, Nikaein N, Svoboda P, Popovic M, Drajic D, Krco S. Traffic models for machineto-machine (M2M) communications: types and applications. In: Machine-to-machine (M2M) Communications. Elsevier; 2015. p. 133–154.

Sanfilippo G, Galinina O, Andreev S, Pizzi S, Araniti G. A concise review of 5G new radio capabilities for directional access at mmWave frequencies. Internet of Things, Smart Spaces, and Next Generation Networks and Systems. 2018; p. 340–354.

Caire G, Taricco G, Biglieri E. Optimum power control over fading channels. IEEE Transactions on Information Theory. 1999;45(5):1468–1489.

Stein W, et al. Sage Mathematics Software, Version 9.2 [Internet]. 2020. Available from: http://www.sagemath.org

Biglieri E, Proakis J, Shamai S. Fading channels: Information-theoretic and communications aspects. IEEE Transactions on Information Theory. 1998;44(6):2619–2692.

Yao X, Yang OW. A queueing analysis of slotted ALOHA systems. In: Proceedings of Canadian Conference on Electrical and Computer Engineering. IEEE; 1993. p. 1234– 1238.

Bertsekas DP, Gallager RG, Humblet P. Data networks. vol. 2. Prentice-Hall International New Jersey; 1992.

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Published

2022-04-24

Issue

Vol. 22 No. 2 (2022)

Section

บทความวิจัย

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