Abstract
This paper exploits for the first time the use of machine learning (ML) based techniques to identify complex structured light patterns under free space optics (FSO) jamming attacks for secure FSO-based applications. Five M-ary modulation schemes, construed using Laguerre and Hermite Gaussian (LG and HG) mode families, were used in this investigation. These include 8-ary LG, 8-ary superposition-LG, 16-ary HG, 16-ary LG and superposition-LG, and 32-ary LG and superposition-LG and HG formats. The work was conducted using experimental demonstrations for two different jammer positions. The convolutional neural network (CNN)-based ML method was utilized to differentiate between the stressed mode patterns. The experimental results show a 100% recognition accuracy for 8-ary LG, 8-ary superposition-LG, and 16-ary HG at 1, −2, and −2 dB signal-to-jammer ratios (SJR), respectively. For SJR values < 0 dB, the standard LG modes are the most affected by jamming and are not recommended for data transmission in such an environment. Besides, the accuracy of determining the jammer direction of arrival was investigated using CNN and a simpler classifier based on linear discriminant analysis (LDA). The results show that advanced networks (e.g., CNN) are required to achieve reliable performance of 100% direction determination accuracy, at −5 dB SJR, as opposed to 97%, at 2 dB SJR, for a simple LDA classifier.
Highlights
It is anticipated in the year 2050 that more than two-thirds of the world population will live in urban areas, where advanced technologies should play a significant role to optimize the life-style in future smart cities
A 15-tap 4 × 4 multi-input multi-output (MIMO) equalizer is used for four multiplexed LG channels each carrying 20 Gbps quadrature phase shift keying (QPSK) signal
For LG modulation set, all modes reach 100% accuracy at signal-to-jammer ratios (SJR) equals 0 dB, except LG01 which requires 1 dB more to reach 100% accuracy
Summary
It is anticipated in the year 2050 that more than two-thirds of the world population will live in urban areas, where advanced technologies should play a significant role to optimize the life-style in future smart cities. FSO has been extensively considered by various communication sectors including wireless communication networks, optical interconnect in data centers, underwater communications, and generation Internet of things systems [2,3,4,5] This is owing to the unique features of FSO technology such as ease and low installation cost, high-throughput, long reach distance, and low link latency. In this regard, different light beam structures were used in data multiplexing and M-ary pattern coding applications [6,7]. The wireless optical link is subject to propagation challenges that limit the FSO efficiency These include intrinsic atmospheric conditions and extrinsic human-made risks (i.e., jamming and interception threats). The authors in [11] exploited AO components to alleviate atmospheric turbulence on the data multiplexed LG mode family, where pre- and post-compensation of weak and moderated turbulence is achieved using an AO feedback closed loop
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