Top

Peer-to-Peer Networking and Applications

Published in:

18-08-2023

Jammer selection for energy harvesting-aided non-orthogonal multiple access: Performance analysis

Author: Khuong Ho-Van

Published in: Peer-to-Peer Networking and Applications | Issue 5/2023

Activate our intelligent search to find suitable subject content or patents.

search-config

AI-assisted search

Off

Abstract

Energy harvesting-aided non-orthogonal multiple access (NOMA) meets critical requirements of modern wireless networks in terms of spectral efficiency, communication reliability, and energy efficiency. However, information security for it has not received greatly attentions from both industry and academia. This paper proposes jammer selection to meliorate its security performance. To promptly assess the efficacy of the proposed jammer selection, we propose explicit formulas of connection/secrecy throughput and outage probability for both far and near users accounting for non-linear feature of energy harvesters. These formulas are corroborated by Monte-Carlo simulations and quickly generate innumerable results to reveal a significant/slight influence of energy harvesting nonlinearity on communications reliability/information security. In addition, there exist limits on target data/secrecy rates to avoid complete connection outage (i.e. connection outage probability is one) and achieve complete security (i.e. secrecy outage probability is one). Additionally, the proposed (NOMA-and-proposed jammer selection) scheme significantly outperforms its counterparts (NOMA-and-random jammer selection and orthogonal multiple access-and-proposed jammer selection) in terms of both security and reliability. Nevertheless, there is a trade-off between reliability and security. Notably, the proposed scheme obtains optimum security/reliability performance with proper selection of time/power splitting coefficient.

previous article Blockchain-based privacy-preserving data-sharing framework using proxy re-encryption scheme and interplanetary file system

next article A block chain-based approach using proof of continuous work consensus algorithm to secure the educational records

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Online-Abonnement

Mit Springer Professional "Wirtschaft+Technik" erhalten Sie Zugriff auf:

über 102.000 Bücher
über 537 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Finance + Banking
Management + Führung
Marketing + Vertrieb
Maschinenbau + Werkstoffe
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Technik"

Online-Abonnement

Mit Springer Professional "Technik" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 390 Zeitschriften

aus folgenden Fachgebieten:

Automobil + Motoren
Bauwesen + Immobilien
Business IT + Informatik
Elektrotechnik + Elektronik
Energie + Nachhaltigkeit
Maschinenbau + Werkstoffe

Jetzt Wissensvorsprung sichern!

inform now

Springer Professional "Wirtschaft"

Online-Abonnement

Mit Springer Professional "Wirtschaft" erhalten Sie Zugriff auf:

über 67.000 Bücher
über 340 Zeitschriften

aus folgenden Fachgebieten:

Bauwesen + Immobilien
Business IT + Informatik
Finance + Banking
Management + Führung
Marketing + Vertrieb
Versicherung + Risiko

Jetzt Wissensvorsprung sichern!

inform now

We study NOMA for each cluster of two users owing to the extensively-acknowledged reality that accreting a quantity of users in each cluster is complex and inefficient [51, 52]. Additionally, the two-user NOMA case was recommended for the 3GPP-LTE-A [53, 54]. Notwithstanding, how to cluster two users is outside the scope of our work (please refer to [6, 29, 36, 42, 55] for deep comprehension on NOMA user grouping).

Although that all jammers jam E simultaneously generates higher amount of jamming power to secure better the desired communications, the current paper does not consider this scenario. This is because of the increasing complexity. Indeed, in order to cancel all jamming signals from J jammers from the desired signals at N and F, they need to synchronize these jamming signals. As such, the higher J, the more complex the synchronization. Accordingly, the jammer selection proposed in this paper reduces the complexity of the synchronization significantly.

This paper researches the case that N implements the detection of \(x_n\) solely if N has restored \(x_f\) accurately. The condition to specify whether N has detected \(x_f\) exactly will be presented in the sequel. Consequently, the interference remained after suppressing \(x_f\) out of \({\tilde{y}_n}\) is neglected.

Due to the high number of curves in Fig. 2, the asymptotic analytical results in Subsections 3.1.3 and 3.2.3 are not presented here. Nevertheless, we double-checked the agreement between the asymptotic analytical results and the simulated results at high P, which exposes the precision of the analysis in Subsections 3.1.3 and 3.2.3.

Guo H et al Multi-UAV cooperative task offloading and resource allocation in 5G advanced and beyond. IEEE Trans Wire Commun. To appear

Fall M et al (2023) Towards sustainable 5G networks: A proposed coordination solution for macro and pico cells to optimize energy efficiency. IEEE Access 11:50794–50804

Lee H et al (2023) Towards 6G hyper-connectivity: Vision, challenges, and key enabling technologies. JCN 25(3):344–354

Ngo et al QT Physical layer security in IRS-assisted cache-enabled satellite communication networks. IEEE Trans Green Commun Netw. To appear

Li Y et al NOMA assisted two-tier VR content transmission: A tile-based approach for QoE optimization. IEEE Trans Mob Comp. To appear

Zhang X et al Generalized approximate message passing based Bayesian learning detectors for uplink grant-free NOMA. IEEE Trans Veh Tech. To appear

Srinath HG et al An efficient NB-IoT compatible GF-NOMA PHY mechanism for mMTC. IEEE IoT J. To appear

Hu B et al (2023) A self-powered rectifier-less series-synchronized switch harvesting on inductor (S-SSHI) interface circuit for flutter-based piezoelectric energy harvesters. IEEE Instrument Measure Mag 26(3):5–13

Halimi MA et al (2023) Rectifier design challenges for wireless energy harvesting/wireless power transfer systems: Broadening bandwidth and extended input power range. IEEE Micro Mag 24(6):54–67

10.

Halimi MA et al (2023) Rectifier circuits for RF energy harvesting and wireless power transfer applications: A comprehensive review based on operating conditions. IEEE Micro Mag 24(1):46–61

11.

Pham-Thi-Dan N et al (2019) Security analysis for cognitive radio network with energy scavenging capable relay over Nakagami-m fading channels. Ho Chi Minh City, Vietnam, IEEE ISEE, pp 68–72

12.

Wang D et al (2020) Primary privacy preserving with joint wireless power and information transfer for cognitive radio networks. IEEE Trans Cog Commun Netw 6(2):683–693

13.

Ge L et al (2020) Performance analysis for multihop cognitive radio networks with energy harvesting by using stochastic geometry. IEEE IoT J 7(2):1154–1163

14.

Bouabdellah M et al (2019) Cooperative energy harvesting cognitive radio networks with spectrum sharing and security constraints. IEEE Access 7:173329–173343

15.

Ghosh S et al On the performance of end-to-end cooperative NOMA-based IoT networks with wireless energy harvesting. IEEE IoT J. To appear

16.

Zhu Z et al (2021) Robust beamforming designs in secure MIMO SWIPT IoT networks with a nonlinear channel model. IEEE IoT J 8(3):1702–1715

17.

Solanki S et al (2020) Performance analysis of Piece-Wise linear model of energy harvesting-based multiuser overlay spectrum sharing networks. IEEE OJCS 1:1820–1836

18.

Babaei M et al (2020) BER performance of full-duplex cognitive radio network with nonlinear energy harvesting. IEEE Trans Green Commun Netw 4(2):448–460

19.

Wang D et al (2020) Performance analysis and resource allocations for a WPCN with a new nonlinear energy harvester model. IEEE OJCOMS 1:1403–1424

20.

Ni L et al (2019) Outage-constrained secrecy energy efficiency optimization for CRNs with non-linear energy harvesting. IEEE Access 7:175213–175221

21.

Wang F et al Secure resource allocation for polarization-based non-linear energy harvesting over 5G cooperative CRNs. IEEE Wire Commun Lett. To appear

22.

Salman H et al PLS-IoT enhancement against eavesdropping via spatially distributed constellation obfuscation. IEEE Wire Commun Lett. To appear

23.

Cao K et al Physical layer security for intelligent reflecting surface aided wireless powered communication systems. IEEE IoT J. To appear

24.

Loukil MH et al Physical layer security at a point-to-point MIMO system with 1-Bit DACs and ADCs. IEEE Wirel Commun Lett. To appear

25.

Katsuki Y et al (2023) Noncoherent massive MIMO with embedded one-way function physical layer security. IEEE Trans Info Forensics Secur 18:3158–3170

26.

Amini C et al (2023) Relay-aided based physical layer security in VLC system with improved noise model. IEEE Trans Commun 71(7):4193–4203

27.

Zheng TX et al (2016) Optimal power allocation for artificial noise under imperfect CSI against spatially random eavesdroppers. IEEE Trans Veh Tech 65(10):8812–8817

28.

Hu J et al (2017) Artificial-noise-aided secure transmission scheme with limited training and feedback overhead. IEEE Trans Wirel Commun 16(1):193–205

29.

Khazali A et al (2022) Energy efficient uplink transmission in cooperative mmWave NOMA networks with wireless power transfer. IEEE Trans Veh Tech 71(1):391–405

30.

Singh CK et al (2022) Energy harvesting in overlay cognitive NOMA systems with hardware impairments. IEEE Sys J 16(2):2648–2659

31.

Shukla AK et al (2021) Performance analysis of energy harvesting-assisted overlay cognitive NOMA systems with incremental relaying. IEEE OJCOMS 2:1558–1576

32.

Liu Y et al (2020) Outage performance analysis for SWIPT-based incremental cooperative NOMA networks with non-linear harvester. IEEE Commun Lett 24(2):287–291

33.

Le QN et al (2021) Full-duplex non-orthogonal multiple access cooperative overlay spectrum-sharing networks with SWIPT. IEEE Trans Green Commun Netw 5(1):322–334

34.

Ma L et al (2021) On the performance of full-duplex cooperative NOMA with non-linear EH. IEEE Access 9:145968–145976

35.

Aswathi V et al (2021) Outage and throughput analysis of full-duplex cooperative NOMA system with energy harvesting. IEEE Trans Veh Tech 70(11):11648–11664

36.

Si Q et al (2021) Cooperative SM-based NOMA scheme with SWIPT. IEEE Trans Veh Tech 70(6):6195–6199

37.

García CE et al (2022) Low-complexity PSO-based resource allocation scheme for cooperative non-linear SWIPT-enabled NOMA. IEEE Access 10:34207–34220

38.

Tran TN et al (2021) SWIPT model adopting a PS framework to aid IoT networks inspired by the emerging cooperative NOMA technique. IEEE Access 9:61489–61512

39.

Liu X et al (2022) Simultaneous wireless information and power transfer based on symbol allocation for GFDM-NOMA cooperative communications. IEEE Wirel Commun Lett 11(2):333–337

40.

Do DT et al (2021) User grouping and energy harvesting in UAV-NOMA system with AF/DF relaying. IEEE Trans Veh Tech 70(11):11855–11868

41.

Agrawal K et al (2020) NOMA with battery-assisted energy harvesting full-duplex relay. IEEE Trans Veh Tech 69(11):13952–13957

42.

Li X et al (2021) Cooperative wireless-powered NOMA relaying for B5G IoT networks with hardware impairments and channel estimation errors. IEEE IoT J 8(7):5453–5467

43.

Bisen S et al (2021) On performance of energy harvested cooperative NOMA under imperfect CSI and imperfect SIC. IEEE Trans Veh Tech 70(9):8993–9005

44.

Zhai C et al (2022) Nonorthogonal multiple access with energy harvesting-based alternate relaying. IEEE Sys J 16(1):327–338MathSciNet

45.

Lei R et al (2021) Secrecy outage performance analysis of cooperative NOMA networks with SWIPT. IEEE Wirel Commun Lett 10(7):1474–1478

46.

Li X et al (2020) Performance analysis of impaired SWIPT NOMA relaying networks over imperfect Weibull channels. IEEE Sys J 14(1):669–672

47.

Aldababsa M et al (2022) Joint transmit-and-receive antenna selection system for MIMO-NOMA with energy harvesting. IEEE Sys J 16(3):4139–4148

48.

Lyu B et al (2022) IRS-assisted downlink and uplink NOMA in wireless powered communication networks. IEEE Trans Veh Tech 71(1):1083–1088MathSciNet

49.

Wu Q et al (2021) IRS-assisted wireless powered NOMA: Do we really need different phase shifts in DL and UL? IEEE Wirel Commun Lett 10(7):1493–1497

50.

Zhang D et al (2021) Throughput maximization for IRS-assisted wireless powered hybrid NOMA and TDMA. IEEE Wirel Commun Lett 10(9):1944–1948

51.

Ardakani FD et al (2022) Joint device pairing, reflection coefficients, and power control for NOMA backscatter systems. IEEE Trans Veh Tech 71(4):4396–4411

52.

Zhao F et al (2022) Integrated satellite-terrestrial networks with coordinated C-NOMA and relay transmission. IEEE Sys J 16(4):5270–5280

53.

Study on Downlink Multiuser Superposition Transmission for LTE (2015) 3GPP. Shanghai, China

54.

Chen G et al (2020) On the performance of cluster-based MIMO NOMA in multi-cell dense networks. IEEE Trans Commun 68(8):4773–4787

55.

Ding Z et al (2016) Impact of user pairing on 5G nonorthogonal multiple-access downlink transmissions. IEEE Trans Veh Tech 65:6010–6023

56.

Fang B et al (2016) Precoding and artificial noise design for cognitive MIMOME wiretap channels. IEEE Trans Veh Tech 65(8):6753–6758

57.

Nguyen VD et al (2016) Joint information and jamming beamforming for secrecy rate maximization in cognitive radio networks. IEEE Trans Info Forensics Secur 11(11):2609–2623

58.

Hu X et al (2016) Secure transmission via jamming in cognitive radio networks with possion spatially distributed eavesdroppers. In: Proceedings of the IEEE PIMRC, Valencia, Spain, pp 1–6

59.

Wu Y et al (2015) Secure beamforming for cognitive radio networks with artificial noise. In: Proceedings of the IEEE WCSP, Nanjing, China, pp 1–5

60.

Zou Y (2017) Physical-layer security for spectrum sharing systems. IEEE Trans Wirel Commun 16(2):1319–1329

61.

Li Z et al (2015) Cooperative jamming for secure communications in MIMO cooperative cognitive radio networks. In: Proceedings of the IEEE ICC, London, UK, pp 7609–7614

62.

Abramowitz M et al (1972) Handbook of mathematical functions with formulas, graphs, and mathematical tables, Tenth printing ed., Washington, DC, USA: U.S. Government Printing Office

Title: Jammer selection for energy harvesting-aided non-orthogonal multiple access: Performance analysis
Author: Khuong Ho-Van
Publication date: 18-08-2023
Publisher: Springer US
Published in: Peer-to-Peer Networking and Applications / Issue 5/2023
Print ISSN: 1936-6442
Electronic ISSN: 1936-6450
DOI: https://doi.org/10.1007/s12083-023-01542-5

Springer Professional

Abstract

Please log in to get access to your license.

Dont have a licence yet? Then find out more about our products and how to get one now:

Springer Professional "Wirtschaft+Technik"

Springer Professional "Technik"

Springer Professional "Wirtschaft"

Other articles of this Issue 5/2023

A cluster reputation-based hierarchical consensus model in blockchain

Privacy-preserving cloud data sharing for healthcare systems with hybrid blockchain

Traffic data security sharing scheme based on blockchain and traceable ring signature for VANETs

Hybrid Grey PIPRECIA and Grey OCRA method-based dynamic multi-criteria decision-making model for mitigating non-cooperating node attacks in WSNs

Bpf-payment: Fair payment for cloud computing with privacy based on blockchain and homomorphic encryption

An efficient blockchain-based anonymous authentication and supervision system

Premium Partner