Litcius/Paper detail

Device-Independent Randomness Amplification and Privatization

Max Kessler, Rotem Arnon-Friedman

2020IEEE Journal on Selected Areas in Information Theory27 citationsDOIOpen Access PDF

Abstract

Secret and perfect randomness is an essential resource in cryptography. Yet, it is not even clear that such exists. It is well known that the tools of classical computer science do not allow us to create secret and perfect randomness from a single weak public source. Quantum physics, on the other hand, allows for such a process, even in the most paranoid cryptographic sense termed “device-independent quantum cryptography”. We propose and prove the security of a new device-independent protocol that takes any single public Santha-Vazirani source as input and creates a secret close to uniform string in the presence of a quantum adversary. Our work is the first to achieve randomness amplification with all the following properties: (1) amplification and “privatization” of a public Santha-Vazirani source with arbitrary bias (2) the use of a device with only two components (3) non-vanishing extraction rate and (4) maximal noise tolerance. In particular, this implies that our protocol is the first protocol that can possibly be implemented with reachable parameters. We achieve these by combining three new tools: a particular family of Bell inequalities, a proof technique to lower bound entropy in the device-independent setting, and a framework for quantum-proof multi-source extractors.

Topics & Concepts

RandomnessQuantum cryptographyProtocol (science)Computer scienceEntropy (arrow of time)Theoretical computer scienceCryptographyUpper and lower boundsCryptographic protocolQuantumMathematicsString (physics)Noise (video)Discrete mathematicsQuantum information scienceLearning with errorsCryptographic primitiveQuantum computerQubitQuantum informationInformation-theoretic securityPublic-key cryptographyNo-teleportation theoremComputer securityRandom number generationQuantum key distributionCryptography and Data SecurityQuantum Information and CryptographyQuantum Mechanics and Applications