Gleipnir:面向量子程序的实际误差分析

Runzhou Tao, Yunong Shi, Jianan Yao, J. Hui, F. Chong, Ronghui Gu
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引用次数: 13

摘要

实际误差分析对于噪声中尺度量子计算的设计、优化和评估至关重要。然而,量子程序中的边界误差是一个巨大的挑战,因为量子误差的影响依赖于指数级大的量子态。在这项工作中,我们提出了Gleipnir,一种用于实际计算量子程序中验证错误界限的新方法。Gleipnir引入了(ρ,δ)-diamond范数,这是一个由近似状态ρ和它到理想状态ρ的距离δ组成的量子谓词约束的误差度量。这个谓词(ρ,δ)可以使用基于矩阵积态的张量网络自适应地计算。Gleipnir具有轻量级逻辑,用于基于(ρ,δ)-钻石范数度量来推理噪声量子程序中的误差界。实验结果表明,Gleipnir能够有效地为10 ~ 100量子位的实际量子程序生成严格的错误边界,并可用于评估量子编译器转换的错误缓解性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Gleipnir: toward practical error analysis for Quantum programs
Practical error analysis is essential for the design, optimization, and evaluation of Noisy Intermediate-Scale Quantum(NISQ) computing. However, bounding errors in quantum programs is a grand challenge, because the effects of quantum errors depend on exponentially large quantum states. In this work, we present Gleipnir, a novel methodology toward practically computing verified error bounds in quantum programs. Gleipnir introduces the (ρ,δ)-diamond norm, an error metric constrained by a quantum predicate consisting of the approximate state ρ and its distance δ to the ideal state ρ. This predicate (ρ,δ) can be computed adaptively using tensor networks based on the Matrix Product States. Gleipnir features a lightweight logic for reasoning about error bounds in noisy quantum programs, based on the (ρ,δ)-diamond norm metric. Our experimental results show that Gleipnir is able to efficiently generate tight error bounds for real-world quantum programs with 10 to 100 qubits, and can be used to evaluate the error mitigation performance of quantum compiler transformations.
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