Dual Connectivity in Non-Stand Alone Deployment mode of 5G in Manhattan Environment

Sheik, Muhammad Usman; Asghar, Muhammad Zeeshan; Jäntti, Riku

doi:10.1109/ICEIC49074.2020.9051202

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Sheik, M. U., Asghar, M. Z., & Jäntti, R. (2020). Dual Connectivity in Non-Stand Alone Deployment mode of 5G in Manhattan Environment. In ICEIC 2020 : Proceedings of the 19th International Conference on Electronics, Information and Communications, Barcelona, Spain (pp. 1-4). IEEE. https://doi.org/10.1109/ICEIC49074.2020.9051202

Authors

Sheik, Muhammad Usman |

Asghar, Muhammad Zeeshan |

Jäntti, Riku

Date

2020

Copyright

The main target of this paper is to analyze the performance of an outdoor user in a dense micro cellular Manhattan grid environment using a ray launching simulation tool. The radio propagation simulations are performed using a Shoot and Bouncing Ray (SBR) method. The network performance is analyzed at three different frequencies i.e. 1.8 GHz, 3.5 GHz, and 28 GHz. Additionally, the benefits of combining LTE and potential 5G frequency bands by using feature of Dual Connectivity (DC) in an outdoor scenario has been highlighted. The considered performance metrics are received signal level, SINR, application throughput. The acquired simulation results from Manhattan canyon street environment reveal that a good 5G outdoor coverage can be provided at 3.5 GHz and 28 GHz while using existing 4G micro sites. The impact of Dual Connectivity at user's throughput is studied in this article, and it is shown user throughput can be doubled by leveraging the benefits of LTE and 5G NR together.

Publisher

IEEE

Parent publication ISBN

978-1-7281-6289-8

Conference

International Conference on Electronics, Information and Communications

Is part of publication

ICEIC 2020 : Proceedings of the 19th International Conference on Electronics, Information and Communications, Barcelona, Spain

Related funder(s)

TEKES

Funding program(s)

TUTL New knowledge and business from research ideas, TEKES

Additional information about funding

This research has been partially supported by the PriMO-5G project funded by the European Unions Horizon 2020 research and innovation programme under grant agreement No 815191, and also partially supported by Business Finland (under grants agreement No. 1916/31/2017 and 6388/31/2018).

License

Except where otherwise noted, this item's license is described as In Copyright