Coverage Probability of Relay-Assisted NOMA Millimeter Wave Networks with Steerable-Beam

In this paper, we consider a relay-assisted non-standalone (NSA) 5G network, where source (S) intends to transmit signals to users by assistance with a relay R, which receives the signals from S operating in microwave frequency and transfers to target users by utilizing steerable-beam non-orthogonal...

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Published inComputer networks (Amsterdam, Netherlands : 1999) Vol. 209; p. 108929
Main Authors Tang, Kun, Jiao, Feiyu, Liu, Xuxun, Che, Wenquan, Xue, Quan
Format Journal Article
LanguageEnglish
Published Amsterdam Elsevier B.V 22.05.2022
Elsevier Sequoia S.A
Subjects
coverage probability
Exact solutions
Mathematical analysis
Microwave frequencies
Millimeter waves
Millimeter-wave
non-orthogonal multiple access
Nonorthogonal multiple access
Optimization
Relay
resource allocation
steerable-beam
steerable-beam
coverage probability
Millimeter-wave
resource allocation
non-orthogonal multiple access
Online AccessGet full text
ISSN1389-1286
1872-7069
DOI10.1016/j.comnet.2022.108929

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Abstract In this paper, we consider a relay-assisted non-standalone (NSA) 5G network, where source (S) intends to transmit signals to users by assistance with a relay R, which receives the signals from S operating in microwave frequency and transfers to target users by utilizing steerable-beam non-orthogonal multiple access (NOMA) scheme operating in millimeter-wave (mmWave) frequency. The steerable-beam NOMA scheme can flexibly switch between single-beam and multi-beam modes according to angle difference of users in NOMA group, i.e., when at least one angle difference is smaller than mmWave beamwidth of main lobe, R adopts a single-beam for achieving NOMA transmission, otherwise multi-beam scheme is used to complete NOMA transmission. For insight into the performance of steerable-beam NOMA scheme, we analyze the coverage probability of the system in-depth for deriving the analytical expressions and approximately closed-form solutions of target users’ coverage probabilities within a NOMA group, where the first user Uo is selected with the shortest distance to the S and the paired user Up is determined based on the minimum angle difference to the first user. However, when R adopts multi-beam, the user with the smallest angle difference to the Uo may not be the best paired user due to the influence of path attenuation and antenna allocation. We then propose a two-stage scheme to obtain optimal user pairing by jointly considering the angle, distance, and sum-rate, while optimizing power allocation subject to maximize the sum-rate. Simulation results illustrate the coverage performance of the system with steerable-beam NOMA scheme for different parameters, and demonstrate the advantages of the proposed two-stage strategy offers a significant improvement in terms of average sum-rate compared to other schemes.
AbstractList In this paper, we consider a relay-assisted non-standalone (NSA) 5G network, where source (S) intends to transmit signals to users by assistance with a relay R, which receives the signals from S operating in microwave frequency and transfers to target users by utilizing steerable-beam non-orthogonal multiple access (NOMA) scheme operating in millimeter-wave (mmWave) frequency. The steerable-beam NOMA scheme can flexibly switch between single-beam and multi-beam modes according to angle difference of users in NOMA group, i.e., when at least one angle difference is smaller than mmWave beamwidth of main lobe, R adopts a single-beam for achieving NOMA transmission, otherwise multi-beam scheme is used to complete NOMA transmission. For insight into the performance of steerable-beam NOMA scheme, we analyze the coverage probability of the system in-depth for deriving the analytical expressions and approximately closed-form solutions of target users' coverage probabilities within a NOMA group, where the first user Uo is selected with the shortest distance to the S and the paired user Up is determined based on the minimum angle difference to the first user. However, when R adopts multi-beam, the user with the smallest angle difference to the Uo may not be the best paired user due to the influence of path attenuation and antenna allocation. We then propose a two-stage scheme to obtain optimal user pairing by jointly considering the angle, distance, and sum-rate, while optimizing power allocation subject to maximize the sum-rate. Simulation results illustrate the coverage performance of the system with steerable-beam NOMA scheme for different parameters, and demonstrate the advantages of the proposed two-stage strategy offers a significant improvement in terms of average sum-rate compared to other schemes.
ArticleNumber 108929
Author Tang, Kun
Che, Wenquan
Liu, Xuxun
Xue, Quan
Jiao, Feiyu
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Keywords steerable-beam
coverage probability
Millimeter-wave
resource allocation
non-orthogonal multiple access
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Snippet In this paper, we consider a relay-assisted non-standalone (NSA) 5G network, where source (S) intends to transmit signals to users by assistance with a relay...
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SubjectTerms coverage probability
Exact solutions
Mathematical analysis
Microwave frequencies
Millimeter waves
Millimeter-wave
non-orthogonal multiple access
Nonorthogonal multiple access
Optimization
Relay
resource allocation
steerable-beam
Title Coverage Probability of Relay-Assisted NOMA Millimeter Wave Networks with Steerable-Beam
URI https://dx.doi.org/10.1016/j.comnet.2022.108929
https://www.proquest.com/docview/2704305492
Volume 209
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