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Annals of Telecommunications

27.06.2017

A new look at AF two-way relaying networks: energy harvesting architecture and impact of co-channel interference

verfasst von: Nguyen Thanh Luan, Dinh-Thuan Do

Erschienen in: Annals of Telecommunications

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Abstract

In this paper, the performance of dual-hop amplify-and-forward (AF) two-way relaying systems is considered, where the terminals and relay are interfered by a finite number of co-channel interferers. In addition, the derived expressions are evaluated in terms of outage probability and throughput in delay-limited transmission mode. To make the analysis mathematically tractable, the unique expressions of outage probability are adopted to deal with energy harvesting protocols related to time switching and power splitting coefficients and expression of the throughput is also calculated. Based on the analytic results, this paper investigates the impact of system parameters such as energy harvesting time/power fractions, number of interferers and signal-to-noise ratio (SNR) on throughput performance. Monte Carlo simulation results are presented to prove the tightness of the proposed energy harvesting two-way relaying system.

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Fußnoten
1
In practice, at the beginning of each block time, the relay node needs a certain amount of energy for operating. In this scenario, the relay node needs a certain amount of energy of previous blocks to initially operate in the next adjacent time slot. However, for simplicity, we assume that initializing energy at the beginning of each frame is not considered.
 
Literatur
1.
Lumpkins W (2014) Nikola Tesla’s dream realized: wireless power energy harvesting. IEEE Consum Electron Mag 3(1):39–42CrossRef
2.
Do D T (2016) Optimal throughput under time power switching based relaying protocol in energy harvesting cooperative networks. Wirel Pers Commun 87(2):551–564CrossRef
3.
Huang K, Zhou X (2015) Cutting the last wires for mobile communications by microwave power transfer. IEEE Commun Mag 53(6):86–93MathSciNetCrossRef
4.
Chen X, Zhang Z, Chen H H, Zhang H (2015) Enhancing wireless information and power transfer by exploiting multi-antenna techniques. IEEE Commun Mag 53(4):133–141CrossRef
5.
Liu Y, Wang L, Elkashlan M, Duong T Q, Nallanathan A (2016) Two-way relay networks with wireless power transfer: design and performance analysis. IET Commun 10(14):1810–1819CrossRef
6.
Rostampoor J, Razavizadeh S M, Lee I (2017) Energy efficiency maximization precoding design for SWIPT in MIMO two-way relay networks. In: IEEE transactions on vehicular technology. doi:10.​1109/​TVT.​2017.​2681942
7.
Zeng Y, Chen H, Zhang R (2016) Bidirectional wireless information and power transfer with a helping relay. IEEE Commun Lett 20(5):862–865CrossRef
8.
Zhang R, Ho C K (2013) MIMO broadcasting for simultaneous wireless information and power transfer. IEEE Trans Wireless Commun 12(5):1989–2001CrossRef
9.
El-Malek A H A, Salhab A M, Zummo S A (2015) Optimal power allocation for enhancing physical layer security in opportunistic relay networks in the presence of co-channel interference. In: Global communications conference (GLOBECOM), 2015 IEEE. IEEE, pp 1–6
10.
Lee D, Lee J H (2011) Outage probability for dual-hop relaying systems with multiple interferers over Rayleigh fading channels. IEEE Trans Veh Technol 60(1):333–338CrossRef
11.
Hoeher P A, Badri-Hoeher S, Xu W, Krakowski C (2005) Single-antenna co-channel interference cancellation for TDMA cellular radio systems. IEEE Wireless Commun 12(2):30–37CrossRef
12.
da Costa D B, Yacoub M D (2011) Outage performance of two hop AF relaying systems with co-channel interferers over Nakagami-m fading. IEEE Commun Lett 15(9):980–982CrossRef
13.
Alouane W H, Hamdi N (2015) Performance analysis of semi-blind two-way AF relaying over generalized-k fading channels. Ann Telecommun 70(9–10):381–394CrossRef
14.
Do D T (2016) Energy-aware two-way relaying networks under imperfect hardware: optimal throughput design and analysis. Telecommun Syst 62(2):449–459CrossRef
15.
Louie R H, Li Y, Vucetic B (2010) Practical physical layer network coding for two-way relay channels: performance analysis and comparison. IEEE Trans Wirel Commun 9:2CrossRef
16.
Guo H, Ge JH (2010) Outage probability of two-way opportunistic amplify-and-forward relaying. Electron Lett 46(13):918– 919CrossRef
17.
Ikki S S, Aissa S (2012) Performance analysis of two-way amplify-and-forward relaying in the presence of co-channel interferences. IEEE Trans Commun 60(4):933–939CrossRefMATH
18.
da Costa D B, Ding H, Yacoub M D, Ge J (2012) Two-way relaying in interference-limited AF cooperative networks over Nakagami- m fading. IEEE Trans Veh Technol 61(8):3766–3771CrossRef
19.
Liang X, Jin S, Wang W, Gao X, Wong KK (2012) Outage probability of amplify-and-forward two-way relay interference-limited systems. IEEE Trans Veh Technol 61(7):3038–3049CrossRef
20.
Gu Y, Aissa S (2014) Interference aided energy harvesting in decode-and-forward relaying systems. In: 2014 IEEE international conference on communications (ICC), pp 5378–5382
21.
Jeffrey A, Zwillinger D (eds) (2007) Table of integrals, series, and products. Academic Press
Metadaten
Titel
A new look at AF two-way relaying networks: energy harvesting architecture and impact of co-channel interference
verfasst von
Nguyen Thanh Luan
Dinh-Thuan Do
Publikationsdatum
27.06.2017
Verlag
Springer International Publishing
Erschienen in
Annals of Telecommunications
Print ISSN: 0003-4347
Elektronische ISSN: 1958-9395
DOI
https://doi.org/10.1007/s12243-017-0590-7