Modeling and Simulation of Physical Layer Security Strategy in Two-Way Cognitive Networks

doi:10.16182/j.issn1004731x.joss.19-0179

Abstract

Abstract: In order to improve the performance of the mobile communication system, the physical layer security transmission models of a two-way cognitive relay network with the primary network and eavesdropper are established, and a joint optimization strategy for relay selection and power allocation is proposed to protect the source-destination transmission against the eavesdropper. It can be seen from the simulation analysis that this non-convex optimization problem has many restrictions, and it is difficult to guarantee the feasibility of the initial solution generated randomly by the PSO algorithm, resulting in the difficulty of obtaining solution. Therefore, a hybrid optimization algorithm based on variable mesh optimization (VMO) and particle swarm optimization (PSO) is proposed. Simulation results show that this algorithm improves the security rate and performance of the secondary network.

Key words: physical layer security, relay selection, power allocation, hybrid optimization, secrecy rate

CLC Number:

TN92

Pan Lei, Li Zan, Zhang Zhili, Li Xiangyang. Modeling and Simulation of Physical Layer Security Strategy in Two-Way Cognitive Networks[J]. Journal of System Simulation, 2021, 33(1): 222-230.

References

[1] Kim Y G, Beaulieu N C.SEP of Decode-and-forward Cooperative Systems with Relay Selection in Nakagami-fading Channels[J]. IEEE Transactions on Vehicular Technology (S0018-9545), 2015, 64(5): 1882-1894.
[2] Sadek A K, Su W, Liu K J R. Multinode Cooperative Communications in Wireless Networks[J]. IEEE Transactions on Signal Processing (S1053-587X), 2007, 55(1): 341-355.
[3] Han Y, Pandharipande A, Ting S H.Cooperative decode-and-forward Relaying for Secondary Spectrum Access[J]. IEEE Transactions on Wireless Communications (S1536-1276), 2009, 8(10): 4945-4950.
[4] Force F S P T. Report of the Spectrum Efficiency Working group[R]. Spectrum Efficiency Working group, 2002.
[5] Mitola J, Maguire G Q.Cognitive Radio: Making Software Radios More Personal[J]. IEEE Personal Communications (S1070-9916), 1999, 6(4): 13-18.
[6] Vosoughi A, Cavallaro J R, Marshall A.Trust-Aware Consensus-Inspired Distributed Cooperative Spectrum Sensing for Cognitive Radio AD Hoc Networks[J]. IEEE Transactions on Cognitive Communications & Networking (S2332-7731), 2017, 2(1): 24-37.
[7] Xu D, Li Q.Resource Allocation for Cognitive Radio With Primary User Secrecy Outage Constraint[J]. IEEE Systems Journal (S1932-8184), 2016, 12(1): 893-904.
[8] Zou Y, Zhu J, Zheng B, et al.An Adaptive Cooperation Diversity Scheme With Best-Relay Selection in Cognitive Radio Networks[J]. IEEE Transactions on Signal Processing (S1053-587X), 2010, 58(10): 5438-5445.
[9] Jiang L, Tian H, Qin C, et al.Secure Beamforming in Wireless-Powered Cooperative Cognitive Radio Networks[J]. IEEE Communications Letters (S1089-7798), 2016, 20(3): 522-525.
[10] Bordon R, Sanchez S M, Mafra S B, et al.Energy Efficient Power Allocation Schemes for A Two-User Network-Coded Cooperative Cognitive Radio Network[J]. IEEE Transactions on Signal Processing (S1053-587X), 2016, 64(7): 1654-1667.
[11] Zou Y.Physical-Layer Security for Spectrum Sharing Systems[J]. IEEE Transactions on Wireless Communications (S1536-1276), 2017, 16(2): 1319-1329.
[12] Zhu F, Gao F, Zhang T, et al.Physical-Layer Security for Full Duplex Communications With Self-Interference Mitigation[J]. IEEE Transactions on Wireless Communications (S1536-1276), 2016, 15(1): 329-340.
[13] Wyner A D.The Wire-Tap Channel[J]. The Bell System Technical Journal (S0005-8580), 1975, 54(8): 1355-1387.
[14] Alotaibi E R, Hamdi K A.Optimal Cooperative Relaying and Jamming for Secure Communication[J]. IEEE Wireless Communications Letters (S2162-2337), 2015, 4(6): 689-692.
[15] Li L, Zhou X, Xu H, et al.Simplified Relay Selection and Power Allocation in Cooperative Cognitive Radio Systems[J]. IEEE Transactions on Wireless Communications (S1536-1276), 2011, 10(1): 33-36.
[16] Javan M R, Mokari N, Alavi F, et al.Resource Allocation in Decode-and-Forward Cooperative Communication Networks With Limited Rate Feedback Channel[J]. IEEE Transactions on Vehicular Technology (S0018-9545), 2017, 66(1): 256-267.