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Simple and practical DIQKD security analysis via BB84-type uncertainty relations and Pauli correlation constraints

Michele Masini, Stefano Pironio, Erik Woodhead

2022Quantum22 citationsDOIOpen Access PDF

Abstract

According to the entropy accumulation theorem, proving the unconditional security of a device-independent quantum key distribution protocol reduces to deriving tradeoff functions, i.e., bounds on the single-round von Neumann entropy of the raw key as a function of Bell linear functionals, conditioned on an eavesdropper's quantum side information. In this work, we describe how the conditional entropy can be bounded in the 2-input/2-output setting, where the analysis can be reduced to qubit systems, by combining entropy bounds for variants of the well-known BB84 protocol with quantum constraints on qubit operators on the bipartite system shared by Alice and Bob. The approach gives analytic bounds on the entropy, or semi-analytic ones in reasonable computation time, which are typically close to optimal. We illustrate the approach on a variant of the device-independent CHSH QKD protocol where both bases are used to generate the key as well as on a more refined analysis of the original single-basis variant with respect to losses. We obtain in particular a detection efficiency threshold slightly below 80.26%, within reach of current experimental capabilities.

Topics & Concepts

BB84Von Neumann entropyQuantum key distributionPauli exclusion principleEntropy (arrow of time)Bounded functionMajorizationMathematicsQuantum computerQubitComputer scienceQuantumApplied mathematicsDiscrete mathematicsQuantum informationQuantum cryptographyQuantum mechanicsQuantum entanglementPhysicsMathematical analysisQuantum Mechanics and ApplicationsQuantum Information and CryptographyQuantum Computing Algorithms and Architecture
Simple and practical DIQKD security analysis via BB84-type uncertainty relations and Pauli correlation constraints | Litcius