Litcius/Paper detail

Secret key rate bounds for quantum key distribution with faulty active phase randomization

Xoel Sixto, Guillermo Currás-Lorenzo, Kiyoshi Tamaki, Marcos Curty

2023EPJ Quantum Technology11 citationsDOIOpen Access PDF

Abstract

Abstract Decoy-state quantum key distribution (QKD) is undoubtedly the most efficient solution to handle multi-photon signals emitted by laser sources, and provides the same secret key rate scaling as ideal single-photon sources. It requires, however, that the phase of each emitted pulse is uniformly random. This might be difficult to guarantee in practice, due to inevitable device imperfections and/or the use of an external phase modulator for phase randomization in an active setup, which limits the possible selected phases to a finite set. Here, we investigate the security of decoy-state QKD when the phase is actively randomized by faulty devices, and show that this technique is quite robust to deviations from the ideal uniformly random scenario. For this, we combine a novel parameter estimation technique based on semi-definite programming, with the use of basis mismatched events, to tightly estimate the parameters that determine the achievable secret key rate. In doing so, we demonstrate that our analysis can significantly outperform previous results that address more restricted scenarios.

Topics & Concepts

Quantum key distributionKey (lock)Computer sciencePhotonPhase (matter)Key generationSet (abstract data type)Ideal (ethics)Topology (electrical circuits)AlgorithmStatistical physicsPhysicsQuantum mechanicsCryptographyMathematicsComputer securityPhilosophyEpistemologyCombinatoricsProgramming languageQuantum Information and CryptographyLaser-Matter Interactions and ApplicationsQuantum Mechanics and Applications