Secure UAV-to-Ground MIMO Communications: Joint Transceiver and Location Optimization

Zhong Zheng; Xinyao Wang; Zesong Fei; Qingqing Wu; Bin Li; Lajos Hanzo

doi:10.1109/TVT.2022.3190272

Secure UAV-to-Ground MIMO Communications: Joint Transceiver and Location Optimization

Zhong Zheng
, Xinyao Wang
, Zesong Fei^*
, Qingqing Wu
, Bin Li
, Lajos Hanzo

^*Corresponding author for this work

School of Information and Electronics

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

4 Citations (Scopus)

Abstract

Unmanned aerial vehicles (UAVs) are foreseen to constitute promising airborne communication devices as a benefit of their superior channel quality. But UAV-to-ground (U2G) communications are vulnerable to eavesdropping. Hence, we conceive a sophisticated physical layer security solution for improving the secrecy rate of multi-antenna aided U2G systems. Explicitly, the secrecy rate of the U2G MIMO wiretap channels is derived by using random matrix theory. The resultant explicit expression is then applied in the joint optimization of the MIMO transceiver and the UAV location relying on an alternating optimization technique. Our numerical results show that the joint transceiver and location optimization conceived facilitates secure communications even in the challenging scenario, where the legitimate channel of confidential information is inferior to the eavesdropping channel.

Original language	English
Pages (from-to)	11661-11676
Number of pages	16
Journal	IEEE Transactions on Vehicular Technology
Volume	71
Issue number	11
DOIs	https://doi.org/10.1109/TVT.2022.3190272
Publication status	Published - 1 Nov 2022

Keywords

MIMO
UAV
alternating optimization
physical layer security
random matrix theory

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10.1109/TVT.2022.3190272

Cite this

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title = "Secure UAV-to-Ground MIMO Communications: Joint Transceiver and Location Optimization",

abstract = "Unmanned aerial vehicles (UAVs) are foreseen to constitute promising airborne communication devices as a benefit of their superior channel quality. But UAV-to-ground (U2G) communications are vulnerable to eavesdropping. Hence, we conceive a sophisticated physical layer security solution for improving the secrecy rate of multi-antenna aided U2G systems. Explicitly, the secrecy rate of the U2G MIMO wiretap channels is derived by using random matrix theory. The resultant explicit expression is then applied in the joint optimization of the MIMO transceiver and the UAV location relying on an alternating optimization technique. Our numerical results show that the joint transceiver and location optimization conceived facilitates secure communications even in the challenging scenario, where the legitimate channel of confidential information is inferior to the eavesdropping channel.",

keywords = "MIMO, UAV, alternating optimization, physical layer security, random matrix theory",

author = "Zhong Zheng and Xinyao Wang and Zesong Fei and Qingqing Wu and Bin Li and Lajos Hanzo",

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T1 - Secure UAV-to-Ground MIMO Communications

T2 - Joint Transceiver and Location Optimization

AU - Zheng, Zhong

AU - Wang, Xinyao

AU - Fei, Zesong

AU - Wu, Qingqing

AU - Li, Bin

AU - Hanzo, Lajos

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N2 - Unmanned aerial vehicles (UAVs) are foreseen to constitute promising airborne communication devices as a benefit of their superior channel quality. But UAV-to-ground (U2G) communications are vulnerable to eavesdropping. Hence, we conceive a sophisticated physical layer security solution for improving the secrecy rate of multi-antenna aided U2G systems. Explicitly, the secrecy rate of the U2G MIMO wiretap channels is derived by using random matrix theory. The resultant explicit expression is then applied in the joint optimization of the MIMO transceiver and the UAV location relying on an alternating optimization technique. Our numerical results show that the joint transceiver and location optimization conceived facilitates secure communications even in the challenging scenario, where the legitimate channel of confidential information is inferior to the eavesdropping channel.

AB - Unmanned aerial vehicles (UAVs) are foreseen to constitute promising airborne communication devices as a benefit of their superior channel quality. But UAV-to-ground (U2G) communications are vulnerable to eavesdropping. Hence, we conceive a sophisticated physical layer security solution for improving the secrecy rate of multi-antenna aided U2G systems. Explicitly, the secrecy rate of the U2G MIMO wiretap channels is derived by using random matrix theory. The resultant explicit expression is then applied in the joint optimization of the MIMO transceiver and the UAV location relying on an alternating optimization technique. Our numerical results show that the joint transceiver and location optimization conceived facilitates secure communications even in the challenging scenario, where the legitimate channel of confidential information is inferior to the eavesdropping channel.

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KW - UAV

KW - alternating optimization

KW - physical layer security

KW - random matrix theory

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JO - IEEE Transactions on Vehicular Technology

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Secure UAV-to-Ground MIMO Communications: Joint Transceiver and Location Optimization

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Keywords

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