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arxiv: 2311.01600 · v3 · pith:IFC3MKCO · submitted 2023-11-02 · quant-ph

Security Proof for Variable-Length Quantum Key Distribution

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classification quant-ph
keywords securityproofvariable-lengthprotocolprotocolsamountattackserror-correction
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We present a security proof for variable-length QKD in the Renner framework against IID collective attacks. Our proof can be lifted to coherent attacks using the postselection technique. Our first main result is a theorem to convert a series of security proofs for fixed-length protocols satisfying certain conditions to a security proof for a variable-length protocol. This conversion requires no new calculations, does not require any changes to the final key lengths or the amount of error-correction information, and at most doubles the security parameter. Our second main result is the description and security proof of a more general class of variable-length QKD protocols, which does not require characterizing the honest behaviour of the channel connecting the users before the execution of the QKD protocol. Instead, these protocols adaptively determine the length of the final key, and the amount of information to be used for error-correction, based upon the observations made during the protocol. We apply these results to the qubit BB84 protocol, and show that variable-length implementations lead to higher expected key rates than the fixed-length implementations.

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Cited by 2 Pith papers

Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Finite-size quantum key distribution rates from R\'enyi entropies using conic optimization

    quant-ph 2025-11 unverdicted novelty 7.0

    A general conic optimization solver computes finite-size QKD rates from Rényi entropies more reliably than prior Frank-Wolfe methods.

  2. Effective discrete-modulated continuous variable QKD under general attacks

    quant-ph 2026-06 unverdicted novelty 6.0

    Finite-size security proof for discrete-modulated CV-QKD under general attacks using dimension reduction and entropy accumulation yields positive rates at block sizes of order 10^8.