Amplifying the Randomness of Weak Sources Correlated With Devices

Wojewódka, Hanna; Brandão, Fernando G. S. L.; Grudka, Andrzej; Horodecki, Karol; Horodecki, Michał; Horodecki, Paweł; Pawłowski, Marcin; Ramanathan, Ravishankar; Stankiewicz, Maciej

doi:10.1109/tit.2017.2738010

Cited by 17 publications

(35 citation statements)

References 17 publications

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“…Other works [23,25,28,29,30,31,32,33] have focused on the second point and study how arbitrarily good randomness can be generated in Bell setups using sources of imperfect randomness. These protocols are often known as randomness amplification protocols [28].…”

Section: Diqrng Protocolmentioning

confidence: 99%

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Certified randomness in quantum physics

Acín¹,

Masanes²

2016

Nature

235

185

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The concept of randomness plays an important role in many disciplines. On one hand, the question of whether random processes exist is fundamental for our understanding of nature. On the other hand, randomness is a resource for cryptography, algorithms and simulations. Standard methods for generating randomness rely on assumptions on the devices that are difficult to meet in practice. However, quantum technologies allow for new methods for generating certified randomness. These methods are known as device-independent because do not rely on any modeling of the devices. Here we review the efforts and challenges to design device-independent randomness generators.

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Section: Diqrng Protocolmentioning

confidence: 99%

“…Under only the assumption of no-signalling, the violation of Bell inequalities certifies the presence of randomness, but requires some initial randomness. Full randomness amplification protocols [23,25,29,30,31,32,33] are not able to completely break this circularity, but relax it as much as possible.…”

Section: Fundamental Questions On Randomnessmentioning

confidence: 99%

Certified randomness in quantum physics

Acín¹,

Masanes²

2016

Nature

235

185

View full text Add to dashboard Cite

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“…The final result was again asymptotic, in the sense that to attain full randomness amplification the user now requires an infinite number of devices. Randomness amplification protocols have been studied by several other works, see for instance (Bouda et al, 2014;Brandão et al, 2016;Chung et al, 2014;Coudron and Yuen, 2013;Grudka et al, 2014;Mironowicz et al, 2015;Ramanathan et al, 2016;Wojewódka et al, 2016). As above, the scope of this section is not to provide a complete description of all the works studying the problem of randomness amplification, but rather to provide a general framework that encompasses most of them.…”

Section: F Nonlocality and Randomness Amplificationmentioning

confidence: 99%

Randomness in quantum mechanics: philosophy, physics and technology

et al. 2017

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This progress report covers recent developments in the area of quantum randomness, which is an extraordinarily interdisciplinary area that belongs not only to physics, but also to philosophy, mathematics, computer science, and technology. For this reason the article contains three parts that will be essentially devoted to different aspects of quantum randomness, and even directed, although not restricted, to various audiences: a philosophical part, a physical part, and a technological part. For these reasons the article is written on an elementary level, combining simple and non-technical descriptions with a concise review of more advanced results. In this way readers of various provenances will be able to gain while reading the article.

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“…Moreover, we also assume that the structure of the box p(x, z|u , w) is fixed independently of the SV source p(u, t, e), i.e., the box is an unknown and arbitrary input-output channel independent of the SV source. This precludes malicious correlations such as in the scenario where for each bit string u taken from the source, a different (possibly local) box tuned to u is supplied, in which case the Bell test may be faked by local boxes [17]. Finally, it is worth noting that no randomness may be extracted under the assumptions stated above in a classical setting, whereas the Bell violation by quantum boxes allows to amplify randomness in a device-independent setting.…”

mentioning

confidence: 99%

“…Important open questions still remain. One interesting question is whether the requirement of strict independence between the SV source and the devices can be relaxed to only require limited independence [17]. Another is to amplify the randomness of more general minentropy sources that do not possess the structure of the Santha-Vazirani source.…”

mentioning

confidence: 99%

Randomness Amplification under Minimal Fundamental Assumptions on the Devices

et al. 2016

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Recently, the physically realistic protocol amplifying the randomness of Santha-Vazirani sources producing cryptographically secure random bits was proposed; however, for reasons of practical relevance, the crucial question remained open regarding whether this can be accomplished under the minimal conditions necessary for the task. Namely, is it possible to achieve randomness amplification using only two no-signaling components and in a situation where the violation of a Bell inequality only guarantees that some outcomes of the device for specific inputs exhibit randomness? Here, we solve this question and present a device-independent protocol for randomness amplification of Santha-Vazirani sources using a device consisting of two nonsignaling components. We show that the protocol can amplify any such source that is not fully deterministic into a fully random source while tolerating a constant noise rate and prove the composable security of the protocol against general no-signaling adversaries. Our main innovation is the proof that even the partial randomness certified by the two-party Bell test [a single input-output pair (u^{*}, x^{*}) for which the conditional probability P(x^{*}|u^{*}) is bounded away from 1 for all no-signaling strategies that optimally violate the Bell inequality] can be used for amplification. We introduce the methodology of a partial tomographic procedure on the empirical statistics obtained in the Bell test that ensures that the outputs constitute a linear min-entropy source of randomness. As a technical novelty that may be of independent interest, we prove that the Santha-Vazirani source satisfies an exponential concentration property given by a recently discovered generalized Chernoff bound.

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Amplifying the Randomness of Weak Sources Correlated With Devices

Cited by 17 publications

References 17 publications

Certified randomness in quantum physics

Certified randomness in quantum physics

Randomness in quantum mechanics: philosophy, physics and technology

Randomness Amplification under Minimal Fundamental Assumptions on the Devices

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