Classical Communication Enhanced Quantum State Verification
Abstract
Quantum state verification provides an efficient approach to characterize the reliability of quantum devices for generating certain target states. The figure of merit of a specific strategy is the estimated infidelity of the tested state to the target state, given a certain number of performed measurements n. Entangled measurements constitute the globally optimal strategy and achieve the scaling that \epsilon is inversely proportional to n. Recent advances show that it is possible to achieve the same scaling simply with non-adaptive local measurements, however, the performance is still worse than the globally optimal bound up to a constant factor. In this work, by introducing classical communication, we experimentally implement an adaptive quantum state verification. The constant-factor is minimized from ~2.5 to 1.5 in this experiment, which means that only 60% measurements are required to achieve a certain value of \epsilon compared to optimal non-adaptive local strategy. Our results indicate that classical communication significantly enhances the performance of quantum state verification, and leads to an efficiency that further approaches the globally optimal bound.
Cite
@article{arxiv.2010.10011,
title = {Classical Communication Enhanced Quantum State Verification},
author = {Wen-Hao Zhang and Xiao Liu and Peng Yin and Xing-Xiang Peng and Gong-Chu Li and Xiao-Ye Xu and Shang Yu and Zhi-Bo Hou and Yong-Jian Han and Jin-Shi Xu and Zong-Quan Zhou and Geng Chen and Chuan-Feng Li and Guang-Can Guo},
journal= {arXiv preprint arXiv:2010.10011},
year = {2020}
}
Comments
arXiv admin note: substantial text overlap with arXiv:1803.10961