Comparative Research of Benchmark Security Capacity of Visible Light Communication Physical Links

doi:10.3969/j.issn.1671-1122.2020.05.008

Abstract

Abstract:

In the process of 5G evolution, the physical layer security of visible light communication (VLC) is gradually earning attention and discussion. However, the current research paradigm is limited to the discussion of visible light communication secure link based on conventional Lambertian LED sources, and there is no quantitative comparative study on the link security characteristics of commercial non-Lambertian sources, especially the benchmark security capacity under non-Lambertian link configurations. In view of the above problems, this paper extends the existent VLC security link modeling scheme, and quantifies the benchmark characteristics of typical non-Lambertian VLC security links within typical indoor environment. The numerical results show that compared with the conventional Lambert beam, the typical non Lambert beams could compress the spatial dynamic range of the benchmark security capacity from 0~10.78 bps/Hz to 0~6.40 bps/Hz, and the relevant mean value is dramatically reduced from the original 5.25 bps/Hz to 2.78 bps/Hz. Therefore, in the design and optimization of the VLC links, the influence of diverse source beams on the secrecy capacity characteristics should be considered, which could be viewed as a potential optimization dimension.

Key words: physical layer security, visible light communication, security capacity, optical beams, non-Lambertian beams

CLC Number:

TP309

DING Jupeng, YI Zhiling, WANG Jintao, YANG Hui. Comparative Research of Benchmark Security Capacity of Visible Light Communication Physical Links[J]. Netinfo Security, 2020, 20(5): 65-71.

Figures/Tables 5

References 17

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参数	取值
场景房间长L、宽W、高H	15.6 m、9 m、3 m
朗伯型光源阵列的朗伯指数m_L	1
单个LED平均光发射功率	150 mW
调制指数α	10%
光源阵列中LED数量	60?60
光源阵列1空间坐标	（2.6,4.5,2.5）
光源阵列2空间坐标	（7.8,4.5,2.5）
光源阵列3空间坐标	（13,4.5,2.5）
3组LED光源阵列俯仰角	-180°
3组LED光源阵列方位角	180°
接收器俯仰角	0°
接收器方位角	180°
接收器视场角θ_FOV	90°
PD探测器面积A_R	1 cm²
PD探测器响应度_r	0.54 mA/mW
合法接收者空间坐标	（7.8,4.5,0.85）
窃听接收者高度	0.85 m
透镜折射指数n	1.5
室内区域的平均噪声功率δ²	1.47?10^-13A²