Abstract
Quantum cryptography is a promising technology that achieves unconditional security, which is essential to a wide range of sensitive applications. In contrast to optical fiber, the free-space optical (FSO) link is efficiently used as a quantum channel without affecting the polarization of transmitted photons. However, the FSO link has several impairments, such as atmospheric turbulence and pointing errors, which affect the performance of the quantum channel. This paper proposes a quantum key distribution (QKD) scheme that uses a time-bin entanglement protocol over the FSO channel that suffers from various channel impairments. Due to the interest in unmanned aerial vehicles (UAVs) and their usefulness for many social, internet-of-things (IoT), civil, and military applications, the proposed QKD-FSO system is integrated with the ground-to-UAV platform. Furthermore, variances in the position and orientation of the UAV are investigated using a tracking system. These variances are considered when evaluating the overall performance of the proposed integrated system. For this purpose, closed-form expressions are obtained for the system average symbol error rate (ASER) and outage probability. The Monte Carlo simulation is used to verify the validity of the proposed expressions. The system security is investigated assuming photon number splitting (PNS) attack. Moreover, the transmit power, time-bin number, and modulation order are optimized to maximize the raw and secret key rates. The results show that for 500 m link, ASER < 10-1 and link outage probability < 10-1 with tolerating boresight displacement up to 30 cm, the system should be configured at receiver’s field-of-view > 22 mrad and signal-to-noise ratio > 7.5 dB which leads SNRth < 2.5 dB and raw key rate maximized by adjusting the number of time bins according to the received SNR.
Highlights
Maintaining a high-performance communication system, including the appropriate security level, is of great importance for many applications
The noise variance σn2 of the gated Geiger-Mode avalanche photodiode (GM-Avalanche photodiode (APD)), assuming no afterpulsing, is [e(PDE.λp+λd) − 1] ngates, where PDE is the photon detection efficiency, λp is the average number of photo-generated carriers per gate, the average number of dark current-generated carriers per gate is λd, and ngates is the total number of gates [43]
The model introduced in this work considers the combined effect of four channel impairments, namely, the atmospheric path loss ha, the atmospheric turbulence ht due to intensity fluctuations of the optical signal while traveling through space, the pointing error loss hp due to misalignment between the beam and detector centers, and the link interruption hpa due to the angle-of-arrival (AoA) fluctuations
Summary
Maintaining a high-performance communication system, including the appropriate security level, is of great importance for many applications. The main contributions of this paper, summarized in Fig., are (1) develop an automatic correction-tracking system that minimizes the errorvariance of tracking system between mobile UAV and fixed ground station; (2) introduce a QKD system over an optical free space channel applying time-bin with EBP considering a variety of channel impairments; (3) propose closedform expressions of average-symbol error rate (ASER) and outage probability for UAV-based FSO communication link considering misalignment due to tracking errors and nonzero boresight pointing errors; (4) obtain expressions of rawkey and secret-key rates to perform the security analysis and capacity of the QKD system; (5) report the optimal value of σo, σp, and θF oV parameters of the proposed system for achieving high performance. The noise variance σn of the gated Geiger-Mode avalanche photodiode (GM-APD), assuming no afterpulsing, is [e(PDE.λp+λd) − 1] ngates, where PDE is the photon detection efficiency, λp is the average number of photo-generated carriers per gate, the average number of dark current-generated carriers per gate is λd, and ngates is the total number of gates [43]
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