Achieving Sustainable Ultra-Dense Heterogeneous Networks for 5G

Jianping An; Kai Yang; Jinsong Wu; Neng Ye; Song Guo; Zhifang Liao

doi:10.1109/MCOM.2017.1700410

Achieving Sustainable Ultra-Dense Heterogeneous Networks for 5G

Jianping An, Kai Yang^*, Jinsong Wu, Neng Ye, Song Guo, Zhifang Liao

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

214 Citations (Scopus)

Abstract

Due to the exponentially increased demands of mobile data traffic, for example, a 1000-fold increase in traffic demand from 4G to 5G, network densification is considered as a key mechanism in the evolution of cellular networks, and UDHN is a promising technique to meet the requirements of explosive data traffic in 5G networks. In the UDHN, the base station is brought closer and closer to users through densely deploying small cells, which results in extremely high spectral efficiency and energy efficiency. In this article, we first present a potential network architecture for the UDHN, and then propose a generalized orthogonal/non-orthogonal random access scheme to improve the network efficiency while reducing the signaling overhead. Simulation results demonstrate the effectiveness of the proposed scheme. Finally, we present some of the key challenges of the UDHN.

Original language	English
Article number	8198807
Pages (from-to)	84-90
Number of pages	7
Journal	IEEE Communications Magazine
Volume	55
Issue number	12
DOIs	https://doi.org/10.1109/MCOM.2017.1700410
Publication status	Published - Dec 2017

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title = "Achieving Sustainable Ultra-Dense Heterogeneous Networks for 5G",

abstract = "Due to the exponentially increased demands of mobile data traffic, for example, a 1000-fold increase in traffic demand from 4G to 5G, network densification is considered as a key mechanism in the evolution of cellular networks, and UDHN is a promising technique to meet the requirements of explosive data traffic in 5G networks. In the UDHN, the base station is brought closer and closer to users through densely deploying small cells, which results in extremely high spectral efficiency and energy efficiency. In this article, we first present a potential network architecture for the UDHN, and then propose a generalized orthogonal/non-orthogonal random access scheme to improve the network efficiency while reducing the signaling overhead. Simulation results demonstrate the effectiveness of the proposed scheme. Finally, we present some of the key challenges of the UDHN.",

author = "Jianping An and Kai Yang and Jinsong Wu and Neng Ye and Song Guo and Zhifang Liao",

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T1 - Achieving Sustainable Ultra-Dense Heterogeneous Networks for 5G

AU - An, Jianping

AU - Yang, Kai

AU - Wu, Jinsong

AU - Ye, Neng

AU - Guo, Song

AU - Liao, Zhifang

PY - 2017/12

Y1 - 2017/12

N2 - Due to the exponentially increased demands of mobile data traffic, for example, a 1000-fold increase in traffic demand from 4G to 5G, network densification is considered as a key mechanism in the evolution of cellular networks, and UDHN is a promising technique to meet the requirements of explosive data traffic in 5G networks. In the UDHN, the base station is brought closer and closer to users through densely deploying small cells, which results in extremely high spectral efficiency and energy efficiency. In this article, we first present a potential network architecture for the UDHN, and then propose a generalized orthogonal/non-orthogonal random access scheme to improve the network efficiency while reducing the signaling overhead. Simulation results demonstrate the effectiveness of the proposed scheme. Finally, we present some of the key challenges of the UDHN.

AB - Due to the exponentially increased demands of mobile data traffic, for example, a 1000-fold increase in traffic demand from 4G to 5G, network densification is considered as a key mechanism in the evolution of cellular networks, and UDHN is a promising technique to meet the requirements of explosive data traffic in 5G networks. In the UDHN, the base station is brought closer and closer to users through densely deploying small cells, which results in extremely high spectral efficiency and energy efficiency. In this article, we first present a potential network architecture for the UDHN, and then propose a generalized orthogonal/non-orthogonal random access scheme to improve the network efficiency while reducing the signaling overhead. Simulation results demonstrate the effectiveness of the proposed scheme. Finally, we present some of the key challenges of the UDHN.

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Achieving Sustainable Ultra-Dense Heterogeneous Networks for 5G

Abstract

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