Sampling and the complexity of nature

D. Hangleiter
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引用次数: 5

Abstract

Randomness is an intrinsic feature of quantum theory. The outcome of any quantum measurement will be random, sampled from a probability distribution that is defined by the measured quantum state. The task of sampling from a prescribed probability distribution is therefore a natural technological application of quantum devices. In the research presented in this thesis, I investigate the complexity-theoretic and physical foundations of quantum sampling algorithms. I assess the computational power of natural quantum simulators and close loopholes in the complexity-theoretic argument for the classical intractability of quantum samplers (Part I). I shed light on how and under which conditions quantum sampling devices can be tested or verified in regimes that are not simulable on classical computers (Part II). Finally, I explore the computational boundary between classical and quantum computing devices (Part III). In particular, I develop efficiently computable measures of the infamous Monte Carlo sign problem and assess those measures both in terms of their practicability as a tool for alleviating or easing the sign problem and the computational complexity of this task. An overarching theme of the thesis is the quantum sign problem which arises due to destructive interference between paths -- an intrinsically quantum effect. The (non-)existence of a sign problem takes on the role as a criterion which delineates the boundary between classical and quantum computing devices. I begin the thesis by identifying the quantum sign problem as a root of the computational intractability of quantum output probabilities. It turns out that the intricate structure of the probability distributions the sign problem gives rise to, prohibits their verification from few samples. In an ironic twist, I show that assessing the intrinsic sign problem of a quantum system is again an intractable problem.
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采样和自然的复杂性
随机性是量子理论的内在特征。任何量子测量的结果都是随机的,从被测量量子态定义的概率分布中采样。因此,从规定的概率分布中抽样的任务是量子器件的自然技术应用。在本文的研究中,我研究了量子采样算法的复杂性理论和物理基础。我评估了天然量子模拟器的计算能力,并弥补了量子采样器经典难解性的复杂性理论论证中的漏洞(第一部分)。我阐明了量子采样设备如何以及在何种条件下可以在经典计算机上无法模拟的制度中进行测试或验证(第二部分)。最后,我探索了经典和量子计算设备之间的计算边界(第三部分)。我为臭名昭著的蒙特卡洛符号问题开发了有效的可计算度量,并评估了这些度量作为减轻或缓解符号问题的工具的实用性以及该任务的计算复杂性。本文的一个主要主题是量子符号问题,它是由于路径之间的破坏性干涉而产生的——本质上是量子效应。符号问题的(不)存在性作为描述经典计算设备和量子计算设备之间边界的标准。我通过确定量子符号问题作为量子输出概率计算难解性的根源来开始论文。事实证明,符号问题引起的概率分布的复杂结构,使它们无法从少数样本中进行验证。具有讽刺意味的是,我表明评估量子系统的内在符号问题也是一个棘手的问题。
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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