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Computing secure key rates for quantum cryptography with untrusted devices

Ernest Y.-Z. Tan, René Schwonnek, Koon Tong Goh, Ignatius William Primaatmaja, Charles Ci Wen Lim

2021npj Quantum Information43 citationsDOIOpen Access PDF

Abstract

Abstract Device-independent quantum key distribution (DIQKD) provides the strongest form of secure key exchange, using only the input–output statistics of the devices to achieve information-theoretic security. Although the basic security principles of DIQKD are now well understood, it remains a technical challenge to derive reliable and robust security bounds for advanced DIQKD protocols that go beyond the previous results based on violations of the CHSH inequality. In this work, we present a framework based on semidefinite programming that gives reliable lower bounds on the asymptotic secret key rate of any QKD protocol using untrusted devices. In particular, our method can in principle be utilized to find achievable secret key rates for any DIQKD protocol, based on the full input–output probability distribution or any choice of Bell inequality. Our method also extends to other DI cryptographic tasks.

Topics & Concepts

Quantum key distributionComputer scienceKey (lock)Key exchangeKey distributionQuantum cryptographyCryptographyProtocol (science)Semidefinite programmingTheoretical computer sciencePublic-key cryptographyComputer securityQuantumMathematicsQuantum informationEncryptionMathematical optimizationQuantum mechanicsPathologyAlternative medicinePhysicsMedicineQuantum Information and CryptographyQuantum Mechanics and ApplicationsQuantum Computing Algorithms and Architecture
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