Increased certification of semi-device independent random numbers using many inputs and more post-processing

Mironowicz, Piotr; Tavakoli, Armin; Hameedi, Alley; Marques, Breno; Pawłowski, Marcin; Bourennane, Mohamed

doi:10.1088/1367-2630/18/6/065004

Cited by 13 publications

(10 citation statements)

References 26 publications

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“…[40] studies the security of BB84 under the even weaker assumption that the dimension of only one of the systems is constrained to be a qubit. [20] shows that considering higher-dimensional systems (still in the SDI model, where a bound on the dimension of the devices is given a priori) can lead to improve rates, albeit at a higher computational cost. [7] consider the task of RNG in the 'measurement-device independent' MDI) setting, where the source, but not the detector, are trusted; their analysis allows them to handle high losses at the untrusted detector and leads to a more practical protocol which (in contrast to fully DI protocols) does not require the generation of entangled states.…”

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confidence: 99%

Focus on device independent quantum information

2016

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The field of quantum information is born out of a sequence of surprising discoveries in the 1980s, all building on the same deep insight: the counter-intuitive quantum properties of particles such as photons or electrons can be put to task in order to accomplish certain computational, cryptographic, and information-theoretic tasks impossible to realize by purely classical means. A famous example is the cryptographic problem of key distribution, for which Bennett and Brassard devised the first quantum protocol in 1984 [6] and whose security relies on the no-cloning principle of quantum mechanics. Another example is the computational problem of factoring large numbers, for which Shor devised the first efficient quantum algorithm in 1994 [32] by exploiting the possibility for quantum systems to evolve in superpositions of exponentially many different states.In this early history, and until very recently, the violation of Bell inequalities was simply seen as yet another feature distinguishing the quantum processing of information from a classical one. It provided one of the initial motivations for developing a better understanding of entangled states; it was recognized as a key factor responsible for the quantum advantage in communication complexity protocols; it was frequently used in experiments to demonstrate oneʼs ability to generate and manipulate entanglement. It also played an important conceptual role, as it established that the predictions of quantum theory, including its claimed information processing advantages, could not be naively reproduced by a classical theory. But overall the manifestation of quantum non-locality was just another way to evidence the weirdness of quantum theory, on par with the nocloning principle or the uncertainty of quantum measurements in having little consequence for practical applications.In very recent years, however, the violation of Bell inequalities has acquired a special status that is starting to revolutionize our understanding of the information-theoretic possibilities of quantum information. Indeed, not only are the properties of quantum states and measurements leading to the violation of Bell inequalities unique in the sense of having no classical explanation, but they also often uniquely single out the quantum system itself. More precisely, given a black-box device that is verifiably violating a Bell inequality, quantum theory allows for a virtually unique way in which this can be accomplished. Furthermore, for the many tasks for which quantum information provides an advantage, there often turns out to be a protocol whose advantage essentially amounts to the sufficiently large violation of a certain Bell inequality.Taken together, these two phenomena lead to the following observation: it is possible to devise quantum information protocols whose correctness can be certified even when they are run with untrusted quantum devices, on which no a priori assumptions are made. Hence the name 'device-independence' (DI) to refer to such protocols. The implications of this are pr...

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confidence: 99%

Focus on device independent quantum information

2016

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“…The most thoroughly researched semi-DI setting is that in which only the Hilbert space dimension is known. This has led to protocols for quantum key distribution [1,2], random number generation [3,4], random access coding [5][6][7], numerous quantum certification protocols [8][9][10][11][12][13][14][15][16][17][18] and several experiments [18][19][20][21][22][23][24]. More recently, also alternative settings have been investigated, based on a bound on the overlap [25][26][27], energy [28][29][30][31] and information content [32,33] of the states.…”

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confidence: 99%

Semi-Device-Independent Framework Based on Restricted Distrust in Prepare-and-Measure Experiments

Tavakoli

2021

Phys. Rev. Lett.

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A semi-device-independent framework for prepare-and-measure experiments is introduced in which an experimenter can tune the degree of distrust in the performance of the quantum devices. In this framework, a receiver operates an uncharacterised measurement device and a sender operates a preparation device that emits states with a bounded fidelity with respect to a set of target states. No assumption on Hilbert space dimension is required. The set of quantum correlations is investigated and bounded from both the interior and the exterior. Furthermore, the optimal performance of quantum state discrimination with bounded distrust is derived and applied to certification of detection efficiency. Quantum-over-classical advantages are demonstrated and the magnitude of distrust compatible with such advantages is explored. Finally, efficient schemes for semi-deviceindependent random number generation are presented.

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“…Apart from the above schemes of self-testing of measurements based on the use of quantum correlations in entangled states, some certification methods for self-testing have been proposed that do not require entanglement [37][38][39][40]. A pair of anticommuting Pauli observables have been self-tested in the prepare and measure scenario [41], employing the quantum advantage of 2 → 1 random access code (RAC) [42,43].…”

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Self-testing of binary Pauli measurements requiring neither entanglement nor any dimensional restriction

Maity,

Mal,

Jebarathinam

et al. 2020

Preprint

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Characterization of quantum devices received from unknown providers is a significant primary task for any quantum information processing protocol. Self-testing protocols are designed for this purpose of certifying quantum components from the observed statistics under a set of minimal assumptions. Here we propose a selftesting protocol for certifying binary Pauli measurements employing the violation of a Leggett-Garg inequality. The scenario based on temporal correlations does not require entanglement, a costly and fragile resource. Moreover, unlike previously proposed self-testing protocols in the prepare and measure scenario, our approach requires neither dimensional restrictions, nor other stringent assumptions on the type of measurements. We further analyse the robustness of this hitherto unexplored domain of self-testing of measurements.

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Increased certification of semi-device independent random numbers using many inputs and more post-processing

Cited by 13 publications

References 26 publications

Focus on device independent quantum information

Focus on device independent quantum information

Semi-Device-Independent Framework Based on Restricted Distrust in Prepare-and-Measure Experiments

Self-testing of binary Pauli measurements requiring neither entanglement nor any dimensional restriction

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