论经典和量子反区分性的最佳误差指数

IF 1.3 3区 物理与天体物理 Q3 PHYSICS, MATHEMATICAL Letters in Mathematical Physics Pub Date : 2024-06-05 DOI:10.1007/s11005-024-01821-z
Hemant K. Mishra, Michael Nussbaum, Mark M. Wilde
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引用次数: 0

摘要

量子态反区分性的概念一直被用来研究量子力学的基础问题。它也被称为量子态消除,因为这种协议的目标是猜测在有限个随机选择的状态中,系统不准备处于哪个状态(也就是说,它可以被视为消除过程的第一步)。反区分性已被用于研究量子态的真实性,排除了量子力学的本体论模型(Pusey 等人,Nat Phys 8(6):475-478, 2012)。因此,鉴于反区分性在量子力学中的既定重要性,我们有必要进一步探索它。在本文中,我们全面研究了经典和量子反区分性的最佳误差指数--最佳误差概率渐近消失为零的速率。我们推导出了经典情况下最佳误差指数的精确表达式,并证明它是由多变量经典切尔诺夫发散给出的。因此,我们的工作为这一发散提供了有意义的操作解释,即反区分一组概率度量的最佳误差指数。对于量子情况,我们提供了最优误差指数的几个界限:由状态的最佳成对切尔诺夫发散给出的下界、单字母半有限编程上界,以及最小和最大多元量子切尔诺夫发散的下界和上界。要获得量子反区分性最佳误差指数的明确表达式,仍是一个未决问题。
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On the optimal error exponents for classical and quantum antidistinguishability

The concept of antidistinguishability of quantum states has been studied to investigate foundational questions in quantum mechanics. It is also called quantum state elimination, because the goal of such a protocol is to guess which state, among finitely many chosen at random, the system is not prepared in (that is, it can be thought of as the first step in a process of elimination). Antidistinguishability has been used to investigate the reality of quantum states, ruling out \(\psi \)-epistemic ontological models of quantum mechanics (Pusey et al. in Nat Phys 8(6):475–478, 2012). Thus, due to the established importance of antidistinguishability in quantum mechanics, exploring it further is warranted. In this paper, we provide a comprehensive study of the optimal error exponent—the rate at which the optimal error probability vanishes to zero asymptotically—for classical and quantum antidistinguishability. We derive an exact expression for the optimal error exponent in the classical case and show that it is given by the multivariate classical Chernoff divergence. Our work thus provides this divergence with a meaningful operational interpretation as the optimal error exponent for antidistinguishing a set of probability measures. For the quantum case, we provide several bounds on the optimal error exponent: a lower bound given by the best pairwise Chernoff divergence of the states, a single-letter semi-definite programming upper bound, and lower and upper bounds in terms of minimal and maximal multivariate quantum Chernoff divergences. It remains an open problem to obtain an explicit expression for the optimal error exponent for quantum antidistinguishability.

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来源期刊
Letters in Mathematical Physics
Letters in Mathematical Physics 物理-物理:数学物理
CiteScore
2.40
自引率
8.30%
发文量
111
审稿时长
3 months
期刊介绍: The aim of Letters in Mathematical Physics is to attract the community''s attention on important and original developments in the area of mathematical physics and contemporary theoretical physics. The journal publishes letters and longer research articles, occasionally also articles containing topical reviews. We are committed to both fast publication and careful refereeing. In addition, the journal offers important contributions to modern mathematics in fields which have a potential physical application, and important developments in theoretical physics which have potential mathematical impact.
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