On the Coexistence of Quantum and Classical Signal Transmission Over Turbulent FSO Channels

Secure data transmission is essential in today's world, and quantum key distribution (QKD) is widely recognized as the technology of choice to enable information-theoretical secure symmetric key generation. While optical fibers are typically used as a transmission channel, wireless transmission...

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Bibliographic Details
Published inJournal of lightwave technology pp. 1 - 8
Main Authors Mantey, S. T., Fernandes, M. A., Fernandes, G. M., Silva, N. A., Guiomar, F. P., Monteiro, P., Pinto, A. N., Muga, N. J.
Format Journal Article
LanguageEnglish
Published IEEE 20.10.2024
Subjects
Adaptive optics
Atmospheric measurements
Attenuation
coexistence
free-space optics
Optical attenuators
Optical fibers
Optical polarization
Optical pulses
Optical transmitters
Optical variables measurement
quantum key distribution
secret key rate
turbulence
Wireless communication
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Summary:Secure data transmission is essential in today's world, and quantum key distribution (QKD) is widely recognized as the technology of choice to enable information-theoretical secure symmetric key generation. While optical fibers are typically used as a transmission channel, wireless transmission offers the flexibility to reach every part of the Earth; moreover, for Earth-Satellite QKD, wireless communication naturally becomes a necessity. In this study, we deployed a fiber-wireless optical system that transmitted a 64-QAM 400 Gbps classical signal for high-rate data exchange and a 1 MHz quantum signal for QKD. The impact of turbulence in the quantum system is evaluated by transmitting single-polarization quantum states through a turbulent free-space channel and by calculating the respective intrinsic quantum bit error rate (QBER). From this, we estimate the system's secret key rate (SKR) and its dependence on turbulence. The effects of atmospheric turbulence on the optical wireless signal were emulated and investigated by using a custom-made atmospheric chamber to induce different turbulent scenarios. The atmospheric chamber allowed us to vary the turbulence in a Rytov variance range from 0.06 to 2.52. The classical signal showed an overall average reliability of 82% for the mentioned turbulence regimes. The results of the quantum signal showed that for Rytov variances up to 1.3, and under the conditions tested, secret key generation is possible, reaching a maximum SKR of 8.7<inline-formula><tex-math notation="LaTeX">\mathbf {\times 10^{-4}}</tex-math></inline-formula> bits per pulse during the produced turbulence regimes.
ISSN:0733-8724
1558-2213
DOI:10.1109/JLT.2024.3484572