Further Improving the Decoy State Quantum Key Distribution Protocol with Advantage Distillation

TL;DR

This paper enhances the decoy state quantum key distribution protocol by applying a refined advantage distillation security proof, leading to improved key rates, longer distances, and better noise tolerance.

Contribution

It provides a new security proof for advantage distillation in decoy state QKD, improving key-rate bounds by accurately accounting for vacuum states.

Findings

Outperforms previous key-rate bounds.

Enables longer communication distances.

Increases noise tolerance in QKD implementations.

Abstract

In this paper, we revisit the application of classical advantage distillation (CAD) to the decoy-state BB84 protocol. Prior work has shown that CAD can greatly improve maximal distances and noise tolerances of the practical decoy state protocol. However, past work in deriving key-rate bounds for this protocol with CAD have assumed a trivial bound on the quantum entropy, whenever Alice sends a vacuum state in a CAD block (i.e., the entropy of such blocks is taken to be zero). Since such rounds contribute, negatively, to the error correction leakage, this results in a correct, though sub-optimal bound. Here, we derive a new proof of security for CAD applied to the decoy state BB84 protocol, computing a bound on Eve's uncertainty in all possible single and vacuum photon events. We use this to derive a new asymptotic key-rate bound which, we show, outperforms prior work, allowing for increased distances and noise tolerances.