Abstract
5G is targeting a peak data rate in the order of 10 Gb/s and at least 100 Mb/s data rate is generally expected to be available everywhere. For fulfilling such 5G broadband targets, massive deployment of small cells is considered as one of the promising solutions. However, inter-cell interference leads to significant limitations on the network throughput in such deployments. In addition, network densification introduces difficulty in network deployment. This paper presents a study on the benefits of advanced receiver in a practical uncoordinated dense small cells deployment. Our aim is to show that advanced receivers can alleviate the need for detailed cell planning. To this end we adopt a hybrid simulation evaluation approach where propagation data are obtained from experimental analysis, and by which we analyse how MIMO constellation and network size impacts to the aim. The experimental data have been obtained using a software defined radio (SDR) testbed network with 12 testbed nodes, configured as either access point or user equipment. Each node features a \(4 \times 4\) or a \(2 \times 2\) MIMO configuration. The results demonstrate that advanced receivers with a larger MIMO antenna configuration significantly improves the throughput performance in a practical dense small cells network due to the interference suppression capability. In addition, the results prove that the operators can rely on uncoordinated deployment of small cells, since the resulting interference can be suppressed by the advanced receiver processing with sufficiently capable MIMO antenna configuration.
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References
Nokia Solutions and Networks: Ten key rules of 5G deployment enabling 1 Tbit/s/km2 in 2030. Nokia Networks white paper (2015)
IMT vision framework and overall objectives of the future development of IMT for 2020 and beyond. International Telecommunication Union (ITU), Radio Communication Study Groups (2015)
Bhushan, N., et al.: Network densification: the dominant theme for wireless evolution into 5G. IEEE Commun. Mag. 52(2), 82–89 (2014)
Mogensen, P., et al.: Centimeter-wave concept small cells. In: IEEE 79th Vehicular Technology Conference (2014)
Choi, J.: Optimal Combining and Detection Statistical Signal Processing for Communications. Camberidge University Press, Camberidge (2010)
Tavares, F.M.L., Berardinelli, G., Mahmood, N.H., Sørensen, T.B., Mogensen, P.: On the potential of interference rejection combining in B4G networks. In: IEEE 78th Vehicular Technology Conference, VTC2013-Fall (2013)
Wassie, D.A., Berardinelli, G., Tavares, F.M.L., Sørensen, T.B., Mogensen, P.: Experimental verification of interference mitigation techniques for 5G small cells. In: IEEE 81st Vehicular Technology Conference, VTC2015-Spring (2015)
National Instrument (2016). http://www.ni.com/labview-communications
National Instrument (2016). http://www.ni.com
Wen, Y., Huang, W., Zhang, Z.: CAZAC sequence and its application in LTE random acess. In: IEEE Information Theory Workshop (ITW) (2006)
Tonelli, O.: Experimental analysis and proof-of-concept of distributed mechnisms for local area wireless network. Ph.D. thesis (2014)
Mogensen, P., et al.: 5G small cell optimized radio design. In: IEEE Globecom, International Workshop on Emerging Techniques for LTE-Advanced and Beyond 4G (2013)
Lampinen, M., Carpio, F.D., Kuosmanen, T., Koivisto, T., Enescu, M.: System-level modeling and evaluation of interference suppression receivers in LTE system. In: IEEE 78th Vehicular Technology Conference, VTC2013-Fall (2013)
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Wassie, D.A., Berardinelli, G., Tavares, F.M.L., Sørensen, T.B., Mogensen, P. (2016). An Experimental Study of Advanced Receivers in a Practical Dense Small Cells Network. In: Madsen, T., Nielsen, J., Pratas, N. (eds) Multiple Access Communications. MACOM 2016. Lecture Notes in Computer Science(), vol 10121. Springer, Cham. https://doi.org/10.1007/978-3-319-51376-8_1
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DOI: https://doi.org/10.1007/978-3-319-51376-8_1
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