Quantifying Bell nonlocality with the trace distance

Brito, Samuraí; Amaral, Bárbara; Chaves, Rafael

doi:10.1103/physreva.97.022111

Cited by 48 publications

(58 citation statements)

References 67 publications

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“…2) as how far a given dcorrelation is from the local polytope defining the correlations (2), with the quantitative aspect that the degree of nonlocality of q that is equal to zero if and only if q is local. Beyond its geometrical and quantitative content, we point out that this distance has computational and numerical appeal, as it can be evaluated efficiently via a linear program [62]. Considering a number of different scenarios, we have uniformly sampled over the NS correlations and computed the distance of each sampled correlation to the set of local correlations.…”

Section: Preliminaries and An Overview Of The Resultsmentioning

confidence: 99%

“…The distribution of our chosen quantifier for nonlocality -based on the trace distance between the probability distribution under test and the set of local correlations introduced in Ref. [62]-has unveiled interesting features in various scenarios. Of particular relevance we have seen that in the scenarios (2, m, 2) and (N, 2, 2) not only the volume of the local set decreases very rapidly but also that the nonlocal points concentrate at a distance from the local set that increases with both m and N. We believe that such a surprising behaviour reflects the signature of the complicated geometry of the nonsignalling and local sets, giving further insight on the relation between local and nonsignalling set.…”

Section: Discussionmentioning

confidence: 99%

“…Sec. V discusses the distribution of the nonlocality measure introduced in [62] in a variety of Bell scenarios and points out to the emergence of concentration phenomena. Finally, we discuss our results as well as potential venues for future work in Sec.…”

Section: Introductionmentioning

confidence: 99%

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Concentration phenomena in the geometry of Bell correlations

et al. 2018

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Bell's theorem shows that local measurements on entangled states give rise to correlations incompatible with local hidden variable models. The degree of quantum nonlocality is not maximal though, as there are even more nonlocal theories beyond quantum theory still compatible with the nonsignalling principle. In spite of decades of research, we still have a very fragmented picture of the whole geometry of these different sets of correlations. Here we employ both analytical and numerical tools to ameliorate that. First, we identify two different classes of Bell scenarios where the nonsignalling correlations can behave very differently: in one case, the correlations are generically quantum and nonlocal while on the other quite the opposite happens as the correlations are generically classical and local. Second, by randomly sampling over nonsignalling correlations, we compute the distribution of a nonlocality quantifier based on the trace distance to the local set. With that we conclude that the nonlocal correlations can show a concentration phenomena: their distribution is peaked at a distance from the local set that increases both with the number of parts or measurements being performed.

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Section: Preliminaries and An Overview Of The Resultsmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

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Concentration phenomena in the geometry of Bell correlations

et al. 2018

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“…Covering both foundational and applied perspectives, a crucial aspect to better understand quantum correlations, their potential advantages over classical resources but also their limitations in the processing of information, relies on understanding their geometry [21]. Many more works [22][23][24][25][26][27][28][29][30] have also revealed a number of interesting geometrical aspects of the set of quantum correlations. Perhaps the best available tool for studying the quantum-postquantum boundary is the Navascues-Pironio-Acin (NPA) hierarchy [31,32], which gives a series of outer approximations converging to a set of quantum correlations Q. Interestingly, in a more recent development [33], it was shown that any nonlocal correlation which belongs to the set of almost quantum correlations Q (1+ab) , the set determined by the (1 + ab) level of the NPA hierarchy [31,32], satisfies all physical principles proposed so far, with two possible exceptions: (i) the information causality principle [11,12] and its generalization [13], and (ii) the recently proposed principle of many-box locality [16].…”

Section: Introductionmentioning

confidence: 99%

Geometry of the quantum set on no-signaling faces

et al. 2019

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Since Bell's theorem we know that quantum mechanics is incompatible with local hidden-variable models, the phenomenon known as quantum nonlocality. However, despite steady progress over the years, precise characterization of the set of quantum correlations remained elusive. There are correlations compatible with the no-signaling principle and still beyond what can be achieved within quantum theory, which has motivated the search for physical principles and computational methods to decide the quantum or postquantum behavior of correlations. Here, we identify a feature of Bell correlations that we call quantum voids: faces of the no-signaling set where all nonlocal correlations are postquantum. Considering the simplest possible Bell scenario, we give a full characterization of quantum voids, also understanding its connections to known principles and its potential use as a dimension witness. arXiv:1812.06057v2 [quant-ph]

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“…Different measures have been considered before, the violation of the CHSH inequality itself [20] and the so called EPR-2 decomposition [23]. Here we employ the trace distance measure introduced in [37], basically quantifying the minimum distance of the nonlocal point in question to the set of local correlations. In the CHSH scenario the trace distance quantifier has been shown to be equivalent to the CHSH inequality violation (up to a constant factor), reason why we consider here as a quantifier NL(p) of the nonlocality of a given distribution p = p(ab|xy) the following quantity:…”

Section: Toolboxmentioning

confidence: 99%

Nonlocality distillation and quantum voids

et al. 2019

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Via nonlocality distillation, a number of copies of a given nonlocal correlation can be turned into a new correlation displaying a higher degree of nonlocality. Apart from its clear relevance in situations where nonlocality is a resource, distillation protocols also play an important role in the understanding of information-theoretical principles for quantum theory. Here, we derive a necessary condition for nonlocality distillation from two copies and apply it, among other results, to show that 1D and 2D quantum voids -faces of the nonlocal simplex set with no quantum realization-can be distilled up to PR-boxes. With that, we generalize previous results in the literature. For instance, showing a broad class of post-quantum correlations that make communication complexity trivial and violate the information causality principle. arXiv:1903.09289v1 [quant-ph]

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Quantifying Bell nonlocality with the trace distance

Cited by 48 publications

References 67 publications

Concentration phenomena in the geometry of Bell correlations

Concentration phenomena in the geometry of Bell correlations

Geometry of the quantum set on no-signaling faces

Nonlocality distillation and quantum voids

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