4G to 5G Low_Latency: Ran, Caching, Channel Characterization Using OFDM –MIMO

Authors

  • Dr. Karney Damodar Associate Professor, Department of ECE, Samskruti College of Engineering and Technology, Hyderabad, India Author
  • Kannan Vanisree Associate Professor, Department of ECE, Samskruti College of Engineering and Technology, Hyderabad, India Author
  • A. Adi Narayana Assistant Professor, St. Mary’s Engineering College, Hyderabad. Author

DOI:

https://doi.org/10.61841/876k3664

Keywords:

5G, Caching, RAN Network, OFDM-MIMO

Abstract

The ongoing headway in the 5G remote advances is requesting higher transfer speed, which is a moving assignment to satisfy with the current recurrence range, for example, underneath 6 GHz. It powers administrators and scientists to go for greater recurrence in the millimeter-wave (mm-wave) range so as to accomplish more prominent data transmission. Empowering mm-wave, be that as it may, will accompany different ways of misfortune, dissipating, blurring, inclusion restriction, entrance misfortune, and different diverse sign constriction issues. We examine the system execution by assessing normal client throughput, normal cell throughput, cell-edge client throughput, top client amount, and ghastly limit. The outcomes definite the noteworthy development in range proficiency of up to 95% for 28 GHz as well as 180% on behalf of 73 GHz is accomplished in correlation through 2.14 GHz. Its consequences likewise demonstrate that the 28 as well as 75 GHz recurrence band can convey up to 80 GHz and 185% of a gigantic improvement in normal cell throughput individually when contrasted with the LTE-A recurrence band as of now. 

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References

[1] Karney, D. (2016). Analytical study on performance of OFDM. International Journal of Advances in Arts,

Sciences and Engineering (ijoaase.com), 4(9).

[2] Obile, W. (2016). Ericsson Mobility Report, ed.

[3] Insights, I. (2014). Worldwide cellphone subscriptions forecast to exceed worldwide population in 2015.

[4] Dahlman, E., Mildh, G., Parkvall, S., Peisa, J., Sachs, J. and Selén, Y. (2014). 5G radio access. Ericsson

review, 91, 42-48.

[5] Seybold, J.S. (2005). Introduction to RF propagation. John Wiley & Sons.

[6] Osseiran, A., Boccardi, F., Braun, V., Kusume, K., Marsch, P., Maternia, M., & Tullberg, H. (2014). Scenarios

for 5G mobile and wireless communications: the vision of the METIS project. IEEE communications

magazine, 52(5), 26-35.

[7] Series, M. (2015). IMT Vision–Framework and overall objectives of the future development of IMT for 2020

and beyond. Recommendation ITU, 2083-0.

[8] Wang, C.X., Wu, S., Bai, L., You, X., Wang, J., & Chih-Lin, I. (2016). Recent advances and future challenges

for massive MIMO channel measurements and models. Science China Information Sciences, 59(2), 1-16.

[9] Elkashlan, M., Duong, T.Q., & Chen, H.H. (2014). Millimeter-wave communications for 5G: fundamentals:

Part I [Guest Editorial]. IEEE Communications Magazine, 52(9), 52-54.

[10] Sun, S., Rappaport, T.S., Thomas, T.A., Ghosh, A., Nguyen, H.C., Kovács, I.Z., & Partyka, A. (2016).

Investigation of prediction accuracy, sensitivity, and parameter stability of large-scale propagation path loss

models for 5G wireless communications. IEEE Transactions on Vehicular Technology, 65(5), 2843-2860.

[11] Rappaport, T.S., MacCartney, G.R., Samimi, M.K., & Sun, S. (2015). Wideband millimeter-wave propagation

measurements and channel models for future wireless communication system design. IEEE Transactions on

Communications, 63(9), 3029-3056.

[12] Al-Samman, A.M., Hindia, M.N., & Rahman, T.A. (2016). Path loss model in outdoor environment at 32 GHz

for 5G system. IEEE 3rd International Symposium on Telecommunication Technologies (ISTT), 9-13.

[13] Bose, A., & Foh, C.H. (2007). A practical path loss model for indoor WiFi positioning enhancement. In 2007

6th International Conference on Information, Communications & Signal Processing, 1-5.

[14] Goulianos, A.A., Brown, T.W., & Stavrou, S. (2008). A novel path-loss model for UWB off-body propagation.

In VTC Spring 2008-IEEE Vehicular Technology Conference, 450-454.

[15] Kumar, G.N.S., & Srinath, A. (2018). Exploration of Accelerating Moving Walkway for Futuristic Transport

System in Congested and Traffical Areas, 616-624.

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Published

18.09.2024

Issue

Vol. 23 No. 1 (2019): 23 (1) 2019

Section

Articles

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How to Cite

Damodar, K., Vanisree, K., & Narayana, A. A. (2024). 4G to 5G Low_Latency: Ran, Caching, Channel Characterization Using OFDM –MIMO. International Journal of Psychosocial Rehabilitation, 23(1), 264-277. https://doi.org/10.61841/876k3664