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Computing conditional entropies for quantum correlations

Peter Brown, Hamza Fawzi, Omar Fawzi

2021Nature Communications44 citationsDOIOpen Access PDF

Abstract

The rates of quantum cryptographic protocols are usually expressed in terms of a conditional entropy minimized over a certain set of quantum states. In particular, in the device-independent setting, the minimization is over all the quantum states jointly held by the adversary and the parties that are consistent with the statistics that are seen by the parties. Here, we introduce a method to approximate such entropic quantities. Applied to the setting of device-independent randomness generation and quantum key distribution, we obtain improvements on protocol rates in various settings. In particular, we find new upper bounds on the minimal global detection efficiency required to perform device-independent quantum key distribution without additional preprocessing. Furthermore, we show that our construction can be readily combined with the entropy accumulation theorem in order to establish full finite-key security proofs for these protocols.

Topics & Concepts

RandomnessQuantum key distributionQuantumComputer scienceEntropy (arrow of time)CryptographyMathematical proofQuantum cryptographyMathematicsConditional entropyKey generationMinificationQuantum algorithmSet (abstract data type)Discrete mathematicsQuantum computerStatistical physicsQuantum annealingUpper and lower boundsKey (lock)Cryptographic primitiveQuantum informationAdversaryKey exchangeLearning with errorsTheoretical computer scienceCryptographic protocolProtocol (science)Random number generationQuantum stateStatistical distanceProbability distributionAlgorithmQuantum Information and CryptographyQuantum Mechanics and ApplicationsAdvanced Statistical Modeling Techniques