没有 I.I.D. 假设的量子态学习特性

Omar Fawzi, Richard Kueng, Damian Markham, Aadil Oufkir
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引用次数: 0

摘要

我们建立了一个学习量子态特性的框架,它超越了独立且同分布(i.i.d.)输入态的假设。我们证明,给定任何学习问题(在合理的假设条件下),为 i.i.d. 输入态设计的分析算法都能适应处理任何性质的输入态,尽管代价是复制复杂性的多项式增加。此外,我们还发现,执行非自适应非相干测量的算法可以扩展到非 i.i.d.input 状态,同时保持相似的错误概率。这使得我们能将 Huang、Kueng 和 Preskill 的经典阴影推广到非 i.i.d. 环境,但代价是少量的低效率损失。此外,我们还能利用克里福德测量法,以一种与理想状态无关的方式,有效地验证任何纯状态。我们的主要技术基于信息论工具支持的德菲内蒂式定理。特别是,我们证明了一个新的随机化局部德菲内蒂定理,它可以引起独立的兴趣。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Learning Properties of Quantum States Without the I.I.D. Assumption
We develop a framework for learning properties of quantum states beyond the assumption of independent and identically distributed (i.i.d.) input states. We prove that, given any learning problem (under reasonable assumptions), an algorithm designed for i.i.d. input states can be adapted to handle input states of any nature, albeit at the expense of a polynomial increase in copy complexity. Furthermore, we establish that algorithms which perform non-adaptive incoherent measurements can be extended to encompass non-i.i.d. input states while maintaining comparable error probabilities. This allows us, among others applications, to generalize the classical shadows of Huang, Kueng, and Preskill to the non-i.i.d. setting at the cost of a small loss in efficiency. Additionally, we can efficiently verify any pure state using Clifford measurements, in a way that is independent of the ideal state. Our main techniques are based on de Finetti-style theorems supported by tools from information theory. In particular, we prove a new randomized local de Finetti theorem that can be of independent interest.
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