Physical Layer Security in Visible Light Communication Systems With Randomly Located Colluding Eavesdroppers

Cho, Sunghwan; Chen, Gaojie; Coon, Justin P.

doi:10.1109/lwc.2018.2820709

Cited by 34 publications

(21 citation statements)

References 30 publications

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“…When the EDs' CSI is not available at the transmitter, it becomes more challenging to characterize the secrecy capacity and quantify the achievable secrecy rate. To overcome this obstacle, researchers have proposed invoking stochastic geometry approaches [109]- [111]. In this context, the locations of the EDs are treated as random variables, and therefore, one may quantify the achievable secrecy rates by averaging over all possible locations.…”

Section: B Single Aumentioning

confidence: 99%

“…In this context, the locations of the EDs are treated as random variables, and therefore, one may quantify the achievable secrecy rates by averaging over all possible locations. In [109], only one randomly located ED is considered, whereas in [110], [111], multiple randomly located EDs were considered. All receivers, including that of the AU, were assumed to be uniformly distributed within the coverage area and their orientation was assumed to be fixed and facing the transmitter.…”

Section: B Single Aumentioning

confidence: 99%

“…In [110], [111], the PPP process was used to model the number of EDs. The main differences between [110], [111] are as follows. The EDs were assumed to be non-colluding in [110] and colluding in [111].…”

Section: B Single Aumentioning

confidence: 99%

See 2 more Smart Citations

Physical Layer Security for Visible Light Communication Systems: A Survey

Arfaoui

Soltani

Tavakkolnia

et al. 2020

IEEE Commun. Surv. Tutorials

138

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Due to the dramatic increase in high data rate services and in order to meet the demands of the fifth-generation (5G) networks, researchers from both academia and industry are exploring advanced transmission techniques, new network architectures and new frequency spectrum such as the visible light and the millimeter wave (mmWave) spectra. Visible light communication (VLC) particularly is an emerging technology that has been introduced as a promising solution for 5G and beyond, owing to the large unexploited spectrum, which translates to significantly high data rates. Although VLC systems are more immune against interference and less susceptible to security vulnerabilities since light does not penetrate through walls, security issues arise naturally in VLC channels due to their open and broadcasting nature, compared to fiber-optic systems. In addition, since VLC is considered to be an enabling technology for 5G, and security is one of the 5G fundamental requirements, security issues should be carefully addressed and resolved in the VLC context. On the other hand, due to the success of physical layer security (PLS) in improving the security of radio-frequency (RF) wireless networks, extending such PLS techniques to VLC systems has been of great interest. Only two survey papers on security in VLC have been published in the literature. However, a comparative and unified survey on PLS for VLC from information theoretic and signal processing point of views is still missing. This paper covers almost all aspects of PLS for VLC, including different channel models, input distributions, network configurations, precoding/signaling strategies, and secrecy capacity and information rates. Furthermore, we propose a number of timely and open research directions for PLS-VLC systems, including the application of measurement-based indoor and outdoor channel models, incorporating user mobility and device orientation into the channel model, and combining VLC and RF systems to realize the potential of such technologies.

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Section: B Single Aumentioning

confidence: 99%

Section: B Single Aumentioning

confidence: 99%

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Physical Layer Security for Visible Light Communication Systems: A Survey

Arfaoui

Soltani

Tavakkolnia

et al. 2020

IEEE Commun. Surv. Tutorials

138

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“…3 shows five cases of the integral region in (18). According to the five cases, the ACS in (18) can be written as (19), the theoretical expression of the ASC is derived as the following theorem.…”

Section: Average Secrecy Capacity Analysismentioning

confidence: 99%

“…With spatially random terminals in VLC, the closed-form expressions for the SOP and the average secrecy capacity (ASC) are derived in [18]. In [19] and [20], the SOP and beamforming are analyzed respectively for VLC with randomly located eavesdroppers. However, the dimming requirement for indoor VLC is not considered in [17]- [20].…”

Section: Introductionmentioning

confidence: 99%

On the Secrecy Performance of Random VLC Networks With Imperfect CSI and Protected Zone

Wang

Qiu

Lin

et al. 2020

IEEE Systems Journal

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This paper investigates the physical-layer security for a random indoor visible light communication (VLC) network with imperfect channel state information (CSI) and a protected zone. The VLC network consists of three nodes, i.e., a transmitter (Alice), a legitimate receiver (Bob), and an eavesdropper (Eve). Alice is fixed in the center of the ceiling, and the emitted signal at Alice satisfies the non-negativity and the dimmable average optical intensity constraint. Bob and Eve are randomly deployed on the receiver plane. By employing the protected zone and considering the imperfect CSI, the stochastic characteristics of the channel gains for both the main and the eavesdropping channels is first analyzed. After that, the closed-form expressions of the average secrecy capacity and the lower bound of secrecy outage probability are derived, respectively. Finally, Monte-Carlo simulations are provided to verify the accuracy of the derived theoretical expressions. Moreover, the impacts of the nominal optical intensity, the dimming target, the protected zone and the imperfect CSI on secrecy performance are discussed, respectively.

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