Low-overhead magic state distillation with color codes

arXiv - PHYS - Quantum Physics Pub Date : 2024-09-12 DOI:arxiv-2409.07707

Seok-Hyung Lee, Felix Thomsen, Nicholas Fazio, Benjamin J. Brown, Stephen D. Bartlett

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Abstract

Fault-tolerant implementation of non-Clifford gates is a major challenge for achieving universal fault-tolerant quantum computing with quantum error-correcting codes. Magic state distillation is the most well-studied method for this but requires significant resources. Hence, it is crucial to tailor and optimize magic state distillation for specific codes from both logical- and physical-level perspectives. In this work, we perform such optimization for two-dimensional color codes, which are promising due to their higher encoding rates compared to surface codes, transversal implementation of Clifford gates, and efficient lattice surgery. We propose two distillation schemes based on the 15-to-1 distillation circuit and lattice surgery, which differ in their methods for handling faulty rotations. Our first scheme uses faulty T-measurement, offering resource efficiency when the target infidelity is above a certain threshold ($\sim 35p^3$ for physical error rate $p$). To achieve lower infidelities while maintaining resource efficiency, our second scheme exploits a distillation-free fault-tolerant magic state preparation protocol, achieving significantly lower infidelities (e.g., $\sim 10^{-19}$ for $p = 10^{-4}$) than the first scheme. Notably, our schemes outperform the best existing magic state distillation methods for color codes by up to about two orders of magnitude in resource costs for a given achievable target infidelity.

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带颜色代码的低成本魔态蒸馏

非克里福德门的容错实现是利用量子纠错码实现通用容错量子计算的一大挑战。魔态蒸馏是这方面研究最深入的方法，但需要大量资源。因此，从逻辑和物理两个层面对特定代码的魔态蒸馏进行分析和优化至关重要。在这项工作中，我们针对二维颜色编码进行了这种优化，由于二维颜色编码与表面编码相比具有更高的编码率、克利福德门的横向实现和高效的晶格手术，因此很有前途。我们提出了两种基于 15 对 1 蒸馏电路和晶格手术的蒸馏方案，它们在处理错误旋转的方法上有所不同。我们的第一种方案使用故障 T 测量，当目标失真度超过一定阈值（物理错误率为 $p$时为 $\sim 35p^3$）时，可提供资源效率。为了在保持资源效率的同时实现更低的不忠度，我们的第二方案利用了无蒸馏容错魔态准备协议，实现了比第一方案更低的不忠度（例如，在p=10^{-4}$时为$\sim 10^{-19}$）。值得注意的是，对于给定的可实现目标不保真度，我们的方案在资源成本上要比现有最好的颜色代码魔态蒸馏方法高出两个数量级。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Quantum Physics

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