Cryptography from Pseudorandom Quantum States

Ananth, Prabhanjan; Qian, Luowen; Yuen, Henry

doi:10.48550/arxiv.2112.10020

Cited by 3 publications

(13 citation statements)

References 14 publications

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“…1 Second, while the internal dynamics of the black hole was modeled as a Haar-random unitary in ref. [1], we reach similar conclusions by modeling the dynamics more realistically as a computationally efficient pseudorandom unitary transformation [10,11]. Third, we show that, even in the presence of infalling agents, the non-isometric map of ref.…”

Section: Introductionsupporting

confidence: 77%

“…ensured when the black hole dynamics has polynomial complexity. This is achieved under the assumption that the internal black hole dynamics is pseudorandom [10] and also that the infaller performs an operation with complexity scaling polynomially in the entropy of the black hole. Moreover, under similar assumptions, we show that the complexity of the black hole S-matrix is polynomial in the black hole entropy.…”

Section: Jhep02(2023)233mentioning

confidence: 99%

“…The existence of such a unitary U would follow from the assumption that pseudorandom unitaries exist [10]. At a high level, this assumption means that there is a family of efficient unitary transformations such that an average over the family cannot be distinguished by computationally bounded observers from an average over Haar measure.…”

Section: Jhep02(2023)233mentioning

confidence: 99%

“…[1], we model the black hole dynamics by a Haar-random unitary transformation, and conclude that the deviations from unitarity induced by the infaller are negligible. Then, more realistically, we assume that the black hole dynamics is pseudorandom [10,11], and infer that deviations from unitarity are small if operations performed by the infaller have complexity polynomial in the black hole entropy. Moreover, under related assumptions, we show that the computational complexity of the black hole S-matrix remains polynomial in its entropy.…”

Section: Introductionmentioning

confidence: 99%

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Complementarity and the unitarity of the black hole S-matrix

Kim

Preskill

2023

J. High Energ. Phys.

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Recently, Akers et al. proposed a non-isometric holographic map from the interior of a black hole to its exterior. Within this model, we study properties of the black hole S-matrix, which are in principle accessible to observers who stay outside the black hole. Specifically, we investigate a scenario in which an infalling agent interacts with radiation both outside and inside the black hole. Because the holographic map involves postselection, the unitarity of the S-matrix is not guaranteed in this scenario, but we find that unitarity is satisfied to very high precision if suitable conditions are met. If the internal black hole dynamics is described by a pseudorandom unitary transformation, and if the operations performed by the infaller have computational complexity scaling polynomially with the black hole entropy, then the S-matrix is unitary up to corrections that are superpolynomially small in the black hole entropy. Furthermore, while in principle quantum computation assisted by postselection can be very powerful, we find under similar assumptions that the S-matrix of an evaporating black hole has polynomial computational complexity.

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Section: Introductionsupporting

confidence: 77%

Section: Jhep02(2023)233mentioning

confidence: 99%

Section: Jhep02(2023)233mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Complementarity and the unitarity of the black hole S-matrix

Kim

Preskill

2023

J. High Energ. Phys.

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“…The frame potential is a user-friendly measure of how random a given ensemble is in terms of operator norms: the smaller the frame potential is, the more chaotic and more complicated the ensembles are, and the more easily we can achieve computational advantages [29,30]. In fact, in certain quantum cryptographic tools, concepts identical or similar to approximate k-designs are used, making use of the exponential separation of complexities between classical and quantum computations [31][32][33][34][35][36][37][38]. The efficient tensor network contraction algorithm is developed in the QTensor framework [39][40][41].…”

mentioning

confidence: 99%

Estimating the randomness of quantum circuit ensembles up to 50 qubits

Liu,

Alexeev

et al. 2022

Preprint

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We develop numerical protocols for estimating the frame potential, the 2-norm distance between a given ensemble and the exact Haar randomness, using the QTensor platform.Our tensor-network-based algorithm has polynomial complexity for shallow circuits and is high performing using CPU and GPU parallelism. We apply the above methods to two problems: the Brown-Susskind conjecture, with local and parallel random circuits in terms of the Haar distance and the approximate k-design properties of the hardware efficient ansätze in quantum machine learning, which induce the barren plateau problem. We estimate frame potentials with these ensembles up to 50 qubits and k = 5, examine the Haar distance of the hardware-efficient ansätze, and verify the Brown-Susskind conjecture numerically. Our work shows that large-scale tensor network simulations could provide important hints toward open problems in quantum information science.

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Encryption with Quantum Public Keys

Grilo¹,

Sattath²,

Vu³

2023

Preprint

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It is an important question to find constructions of quantum cryptographic protocols which rely on weaker computational assumptions than classical protocols. Recently, it has been shown that oblivious transfer and multi-party computation can be constructed from one-way functions, whereas this is impossible in the classical setting in a black-box way.In this work, we study the question of building quantum public-key encryption schemes from one-way functions and even weaker assumptions. Firstly, we revisit the definition of IND-CPA security to this setting. Then, we propose three schemes for quantum public-key encryption from one-way functions, pseudorandom function-like states with proof of deletion and pseudorandom function-like states, respectively.

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Cryptography from Pseudorandom Quantum States

Cited by 3 publications

References 14 publications

Complementarity and the unitarity of the black hole S-matrix

Complementarity and the unitarity of the black hole S-matrix

Estimating the randomness of quantum circuit ensembles up to 50 qubits

Encryption with Quantum Public Keys

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