High-dimensional multi-input quantum random access codes and mutually unbiased bases
Abstract
Quantum random access codes (QRACs) provide a basic tool for demonstrating the advantages of quantum resources and protocols, which have a wide range of applications in quantum information processing tasks. However, the investigation and application of high-dimensional multi-input QRACs are still lacking. Here, we present a general method to find the maximum success probability of QRACs. In particular, we give the analytical solution for maximum success probability of QRACs when measurement bases are mutually unbiased bases (MUBs). Based on the analytical solution, we show the relationship between MUBs and QRACs. First, we provide a systematic method of searching for the operational inequivalence of MUBs (OI-MUBs) when the dimension is a prime power. Second, we theoretically prove that, surprisingly, the commonly used Galois MUBs are not the optimal measurement bases to obtain the maximum success probability of QRACs, which indicates a breakthrough according to the traditional conjecture regarding the optimal measurement bases. Furthermore, based on high-fidelity high-dimensional quantum states of orbital angular momentum, we experimentally achieve two-input and three-input QRACs up to dimension 11. We experimentally confirm the OI-MUBs when . Our results open alternative avenues for investigating the foundational properties of quantum mechanics and quantum network coding.
Cite
@article{arxiv.2111.08890,
title = {High-dimensional multi-input quantum random access codes and mutually unbiased bases},
author = {Rui-Heng Miao and Zhao-Di Liu and Yong-Nan Sun and Chen-Xi Ning and Chuan-Feng Li and Guang-Can Guo},
journal= {arXiv preprint arXiv:2111.08890},
year = {2022}
}