The service required quality ensure model of LTE technology downlink

Authors

  • Sergey Garkusha Kharkiv National University of Radio Electronics Lenina 16, Kharkov, Ukraine, 61166, Ukraine
  • Aymen Mohammed Khodayer Al-Dulaimi Kharkiv National University of Radio Electronics Lenina 16, Kharkov, Ukraine, 61166, Ukraine
  • Haider Dheyaa Kamil Al-Janabi Kharkiv National University of Radio Electronics Lenina 16, Kharkov, Ukraine, 61166, Ukraine

DOI:

https://doi.org/10.15587/1729-4061.2013.16390

Keywords:

LTE, mathematical model, required rate, objective function, resource block

Abstract

Article presents a mathematical model of resource blocks distribution in LTE technology downlink.

Offered model aims at providing guaranteed quality of service wireless users by user stations allocating of required transmission rates. Comparative analysis of obtained solutions by using different objective functions. Using various kinds of objective functions in offered model is directed to resource blocks allocation of minimum downlink or a minimum data transmission rate of each user station. It was found the greatest savings of time frequency resource allows objective function aimed at minimizing number of used resource blocks. The model offered in classes of service CoS corresponds to Class B each providing each user station a guaranteed transmission rate, with access to additional (nonguaranteed) bandwidth

Author Biographies

Sergey Garkusha, Kharkiv National University of Radio Electronics Lenina 16, Kharkov, Ukraine, 61166

Docent

Department of Telecommunications systems

Aymen Mohammed Khodayer Al-Dulaimi, Kharkiv National University of Radio Electronics Lenina 16, Kharkov, Ukraine, 61166

Master

Department of Telecommunications systems

Haider Dheyaa Kamil Al-Janabi, Kharkiv National University of Radio Electronics Lenina 16, Kharkov, Ukraine, 61166

Master

Department of Telecommunications systems

References

  1. 3GPP TS 36.211. 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Physical Channels and Modulation [Text]. – Введ. 2012. – Valbonne, France : Sophia Antipolis, 2012. – 108 p.
  2. Ghosh, A. Fundamentals of LTE [Text] / A. Ghosh, J. Zhang, R. Muhamed, J. Cr. Andrews . – USA: Prentice Hall, 2010. – 464 p.
  3. Iosif, O. On the Analysis of Packet Scheduling in Downlink 3GPP LTE System [Text] / O. Iosif, I Banica. // Proc. of the Fourth International Conference on Communication Theory, Reliability, and Quality of Service (Mart 2011). – 2011. – pp. 99–102.
  4. 3G Evolution – HSPA and LTE for Mobile Broadband [Text] / E. Dahlman, S. Parkvall, J. Skold, P. Beming. – Academic Press, 2008. – 608 p.
  5. Kawser, M. T. Performance Comparison between Round Robin and Proportional Fair Scheduling Methods for LTE [Text] / M. T. Kawser, H. M. A. B. Farid, A. R. Hasin, A. M. J. Sadik, I. К. Razu // International Journal of Information and Electronics Engineering. – 2012. – V. 2, № 5. – pp. 678–681.
  6. Galaviz, G. A resource block organization strategy for scheduling in carrier aggregated systems [Text] / G. Galaviz, D. H. Covarrubias, A. G. Andrade, S. Villarreal // EURASIP Journal on Wireless Communications and Networking. – 2012. – pp. 107–124.
  7. Girici, T. Proportional Fair Scheduling Algorithm in OFDMA-BasedWireless Systems with QoS Constraints [Текст] / T. Girici, C. Zhu, J. R. Agre, A. Ephremides // Journal of communications and networks. – 2010. – V. 12, № 1. – pp. 30–42.
  8. Tang, Z. Traffic Scheduling for LTE Advanced [Text] / Z. Tang. – Linkцping : Division of Communication Systems, 2010. – 71 p.
  9. Hussain, S. Dynamic Radio Resource Management in 3GPP LTE [Text] / S. Hussain. – Karlskrona : Blekinge Institute of Technology. – 2009. – 58 p.
  10. Østerbø, O. Scheduling and Capacity Estimation in LTE [Text] / O. Østerbø // Advances in electronics and telecommunications. – 2011. – Vol. 2, No. 3. – pp. 31-42.
  11. 3GPP TS 36.211. (2012). 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA); Physical Channels and Modulation. Valbonne, France: Sophia Antipolis, Release 11, 108.
  12. Ghosh, A., Zhang, J., Muhamed, R., Andrews, J. Cr. (2010). Fundamentals of LTE. Prentice Hall, USA, 464.
  13. Iosif, O., Banica, I. (2011). On the Analysis of Packet Scheduling in Downlink 3GPP LTE System. The Fourth International Conference on Communication Theory, Reliability, and Quality of Service (CTRQ 2011), 99–102.
  14. Dahlman, E., Parkvall, S., Skold, J., Beming, P. (2008). 3G Evolution – HSPA and LTE for Mobile Broadband. Academic Press, 608.
  15. Kawser, M.T., Farid, H. M. A. B., Hasin, A. R., Sadik, A. M. J., Razu, I. К. (2012). Performance Comparison between Round Robin and Proportional Fair Scheduling Methods for LTE. International Journal of Information and Electronics Engineering, V.2, № 5, 678–681.
  16. Galaviz, G., Covarrubias, D. H., Andrade, A. G., Villarreal, S. (2012). A resource block organization strategy for scheduling in carrier aggregated systems. EURASIP Journal on Wireless Communications and Networking, 107–124.
  17. Girici, T., Zhu, C., Agre, J. R., Ephremides, A. (2010). Proportional Fair Scheduling Algorithm in OFDMA-BasedWireless Systems with QoS Constraints. Journal of communications and networks, V.12, № 1, 30–42.
  18. Tang, Z. (2010). Traffic Scheduling for LTE Advanced. Linkцping: Division of Communication Systems, 71.
  19. Hussain, S. (2009). Dynamic Radio Resource Management in 3GPP LTE. Karlskrona: Blekinge Institute of Technology, 58.
  20. Østerbø, O. (2011). Scheduling and Capacity Estimation in LTE. Advances in electronics and telecommunications, Vol. 2, No. 3, 31-42.

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Published

2013-08-15

How to Cite

Garkusha, S., Al-Dulaimi, A. M. K., & Al-Janabi, H. D. K. (2013). The service required quality ensure model of LTE technology downlink. Eastern-European Journal of Enterprise Technologies, 4(9(64), 35–38. https://doi.org/10.15587/1729-4061.2013.16390

Issue

Vol. 4 No. 9(64) (2013): Information and control systems

Section

Information and controlling system

License

Copyright (c) 2014 Sergey Garkusha, Aymen Mohammed Khodayer Al-Dulaimi, Haider Dheyaa Kamil Al-Janabi

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