Analytical finite-key security proof for decoy-state QKD that incorporates state-preparation flaws, bit/basis side-channel leakage and correlations, intensity fluctuations, and detection-efficiency mismatches.
Numerical security analysis for practical quantum key distribution
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
Quantum key distribution (QKD) promises information-theoretic security based on quantum mechanics and idealized device models. Practical implementations, however, deviate from these models due to unavoidable device imperfections, and existing security proofs fall short of capturing the complexity of real-world systems. Here we introduce a versatile numerical finite-key security framework valid against general coherent attacks and applicable to a broad class of practical QKD setups. It accommodates most relevant imperfections at both transmitter and receiver, including non-independent-and-identically-distributed (non-IID) signals arising in high-speed QKD systems due to the limited bandwidth of optical modulators, while requiring only partial characterization of the apparatuses. We demonstrate the power of our framework by proving the security of a realistic decoy-state QKD implementation with laser sources, providing a practical route towards rigorous security certification of real-world QKD setups.
fields
quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
A SLED-based 1.25 GHz QKD source achieves intrinsic phase randomization between pulses while maintaining >99% visibility within pulses.
citing papers explorer
-
Finite-key security analysis of decoy-state QKD with source and detector imperfections
Analytical finite-key security proof for decoy-state QKD that incorporates state-preparation flaws, bit/basis side-channel leakage and correlations, intensity fluctuations, and detection-efficiency mismatches.
-
Phase-correlation-free quantum key distribution source operating at gigahertz rates
A SLED-based 1.25 GHz QKD source achieves intrinsic phase randomization between pulses while maintaining >99% visibility within pulses.