Prefixed-threshold real-time selection for correlated turbulent channel model for quantum key distribution with modulating retro-reflectors

In most of the realistic measurement device-independent quantum key distribution (MDI-QKD) systems, efficient, real-time feedback controls are required to maintain system stability when facing disturbance from either external environment or imperfect internal components. Traditionally, people either use a “scanning-and-transmitting” program or insert an extra device to make a phase reference frame calibration for a stable high-visibility interference, resulting in higher system complexity and lower transmission efficiency. In this work, we build a machine learning-assisted MDI-QKD system, where a machine learning model—the long short-term memory (LSTM) network—is for the first time to apply onto the MDI-QKD system for reference frame calibrations. In this machine learning-assisted MDI-QKD system, one can predict out the phase drift between the two users in advance, and actively perform real-time phase compensations, dramatically increasing the key transmission efficiency. Furthermore, we carry out corresponding experimental demonstration over 100 km and 250 km commercial standard single-mode fibers, verifying the effectiveness of the approach.

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A model to estimate performance of space-based quantum communication protocols including quantum key distribution systems

The Journal of Defense Modeling and Simulation Applications Methodology Technology ◽

10.1177/1548512916684562 ◽

2017 ◽

Vol 16 (1) ◽

pp. 5-13

Author(s):

Jonathan C Denton ◽

Douglas D Hodson ◽

Richard G Cobb ◽

Logan O Mailloux ◽

Michael R Grimaila ◽

...

Keyword(s):

Quantum Key Distribution ◽

Distribution Systems ◽

Quantum Communication ◽

Channel Model ◽

Communication Protocols ◽

Key Distribution ◽

General Purpose ◽

Optical Channel ◽

Use Case ◽

Atmospheric Conditions

This work presents a model to estimate the performance of space-based, optical-based, quantum communication protocols. This model consists of components to account for optical channel propagation effects based on orbit selection and atmospheric conditions. The model presented is general purpose and can be leveraged to evaluate the performance of a variety of quantum communication protocols, of which, Quantum Key Distribution (QKD) systems served as our motivating use case of particular interest. To verify correctness, the model is used to produce estimates for QKD system scenarios and compared to published results. The performance of QKD systems is of interest as distance limitations for terrestrial-based systems have hindered their practical use, and satellite-based designs that can generate a shared key between two distant geographic locations have been proposed. For this application domain, a review of space-based designs that illuminate the need for a free space downlink channel model is presented followed by its development to estimate the performance of quantum exchanges between a satellite and ground site.

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