Related papers: Efficient verification of continuous-variable quantum states and devices without assuming identical and independent operations

Efficient verification of continuous-variable quantum states and devices without assuming identical and independent operations

URL: http://arxiv.org/abs/2012.03784v3
Date: Wed, 16 Jun 2021 14:47:56 GMT
Title: Efficient verification of continuous-variable quantum states and devices without assuming identical and independent operations
Authors: Ya-Dong Wu, Ge Bai, Giulio Chiribella, and Nana Liu
Abstract summary: We propose the first set of reliable protocols for verifying multimode continuous-variable entangled states and devices. Although not fully universal, these protocols are applicable to Gaussian quantum states, non-Gaussian hypergraph states, as well as amplification, attenuation, and purification of noisy coherent states.
Score: 1.2862023695904006
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Continuous-variable quantum information, encoded into infinite-dimensional quantum systems, is a promising platform for the realization of many quantum information protocols, including quantum computation, quantum metrology, quantum cryptography, and quantum communication. To successfully demonstrate these protocols, an essential step is the certification of multimode continuous-variable quantum states and quantum devices. This problem is well studied under the assumption that multiple uses of the same device result into identical and independently distributed (i.i.d.) operations. However, in realistic scenarios, identical and independent state preparation and calls to the quantum devices cannot be generally guaranteed. Important instances include adversarial scenarios and instances of time-dependent and correlated noise. In this paper, we propose the first set of reliable protocols for verifying multimode continuous-variable entangled states and devices in these non-i.i.d scenarios. Although not fully universal, these protocols are applicable to Gaussian quantum states, non-Gaussian hypergraph states, as well as amplification, attenuation, and purification of noisy coherent states.

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