Practical distributed quantum information processing with LOCCNet

Zhao, Xuanqiang; Zhao, Benchi; Wang, Zihe; Song, Zhixin; Wang, Xin

doi:10.1038/s41534-021-00496-x

Cited by 18 publications

(42 citation statements)

References 86 publications

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“…We find that the optimal protocol for n = 4 achieves the same fidelity as the concatenated DEJMPS protocol for n = 5, and can be executed with a circuit of the same depth as the concatenated DEJMPS protocol. This protocol achieves the same distillation statistics as the protocol found with different means in the recent work from [49]. For n = 5 there is a large gap between the optimised protocols and the concatenated DEJMPS protocol.…”

Section: Achieved Distillation Statistics For N-fold Werner Statessupporting

confidence: 62%

Enumerating all bilocal Clifford distillation protocols through symmetry reduction

Jansen

Goodenough

Bone

et al. 2022

Quantum

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Entanglement distillation is an essential building block in quantum communication protocols. Here, we study the class of near-term implementable distillation protocols that use bilocal Clifford operations followed by a single round of communication. We introduce tools to enumerate and optimise over all protocols for up to n=5 (not necessarily equal) Bell-diagonal states using a commodity desktop computer. Furthermore, by exploiting the symmetries of the input states, we find all protocols for up to n=8 copies of a Werner state. For the latter case, we present circuits that achieve the highest fidelity with perfect operations and no decoherence. These circuits have modest depth and number of two-qubit gates. Our results are based on a correspondence between distillation protocols and double cosets of the symplectic group, and improve on previously known protocols.

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Section: Achieved Distillation Statistics For N-fold Werner Statessupporting

confidence: 62%

Enumerating all bilocal Clifford distillation protocols through symmetry reduction

Jansen

Goodenough

Bone

et al. 2022

Quantum

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“…As explained in the main text, to obtain states with further lower infidelity, we consider distillation protocols on two-copy of the output qubits produced from hybrid LVQCs or direct swap approach. Various entanglement distillation protocols on DV systems have been proposed, including BBPSSW [30], DEJMPS [31] and LOC-CNet [33]. We mainly focus on the DEJMPS protocol which is proved to be optimal for bell-diagonal states with rank up to three, and a DEJMPS-inspired DV LVQC, shown in Fig.…”

Section: Appendix F: Qubit Distllation Protocolsmentioning

confidence: 99%

“…Distillation protocols.-Next, we design distillation protocols to obtain high-fidelity DV entanglement ρq,q between two transmon qubits from the noisy two-mode squeezing between microwave modes ρm,m . Distillation has been explored separately for either DV [26,[30][31][32][33][34][35][36][37] or CV [38][39][40][41][42][43][44][45][46][47][48] entanglement. Here, we require a hybrid distillation protocol that produces high fidelity DV entanglement from noisy CV entanglement.…”

mentioning

confidence: 99%

Entangling remote microwave quantum computers with hybrid entanglement swap and variational distillation

Zhang,

Wu,

Fan

et al. 2022

Preprint

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Superconducting microwave circuits with Josephson junctions are a major platform for quantum computing. To unleash their full capabilities, the cooperative operation of multiple microwave superconducting circuits is required. Therefore, designing an efficient protocol to distribute microwave entanglement remotely becomes a crucial open problem. Here, we propose a continuous-variable entanglement-swap approach based on optical-microwave entanglement generation, which can boost the ultimate rate by two orders of magnitude at state-of-the-art parameter region, compared with traditional approaches. We further empower the protocol with a hybrid variational entanglement distillation component to provide huge advantage in the infidelity-versus-success-probability tradeoff. Our protocol can be realized with near-term device performance, and is robust against nonperfections such as optical loss and noise. Therefore, our work provides a practical method to realize efficient quantum links for superconducting microwave quantum computers.

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“…Both distributed quantum computation and delegated quantum computation have been investigated broadly; see references [ 13 , 14 , 15 , 16 , 17 , 18 , 19 , 20 , 21 ] and [ 6 , 11 , 22 , 23 , 24 , 25 , 26 , 27 , 28 ], respectively. Typically, the distributed architecture for quantum computation makes use of photons as flying qubits between computational nodes, where each node is equipped with a quantum computer.…”

Section: Introductionmentioning

confidence: 99%

A Distributed Architecture for Secure Delegated Quantum Computation

Zhu

Quan

et al. 2022

Entropy

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In this paper, we propose a distributed secure delegated quantum computation protocol, by which an almost classical client can delegate a (dk)-qubit quantum circuit to d quantum servers, where each server is equipped with a 2k-qubit register that is used to process only k qubits of the delegated quantum circuit. None of servers can learn any information about the input and output of the computation. The only requirement for the client is that he or she has ability to prepare four possible qubits in the state of (|0⟩+eiθ|1⟩)/2, where θ∈{0,π/2,π,3π/2}. The only requirement for servers is that each pair of them share some entangled states (|0⟩|+⟩+|1⟩|−⟩)/2 as ancillary qubits. Instead of assuming that all servers are interconnected directly by quantum channels, we introduce a third party in our protocol that is designed to distribute the entangled states between those servers. This would simplify the quantum network because the servers do not need to share a quantum channel. In the end, we show that our protocol can guarantee unconditional security of the computation under the situation where all servers, including the third party, are honest-but-curious and allowed to cooperate with each other.

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Practical distributed quantum information processing with LOCCNet

Cited by 18 publications

References 86 publications

Enumerating all bilocal Clifford distillation protocols through symmetry reduction

Enumerating all bilocal Clifford distillation protocols through symmetry reduction

Entangling remote microwave quantum computers with hybrid entanglement swap and variational distillation

A Distributed Architecture for Secure Delegated Quantum Computation

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