Tightening Continuity Bounds for Entropies and Bounds on Quantum Capacities

Michael G. Jabbour;Nilanjana Datta
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Abstract

Uniform continuity bounds on entropies are generally expressed in terms of a single distance measure between probability distributions or quantum states, typically, the total variation- or trace distance. However, if an additional distance measure is known, the continuity bounds can be significantly strengthened. Here, we prove a tight uniform continuity bound for the Shannon entropy in terms of both the local- and total variation distances, sharpening an inequality in (Sason, 2013). We also obtain a uniform continuity bound for the von Neumann entropy in terms of both the operator norm- and trace distances. We then apply our results to compute upper bounds on channel capacities. We first refine the concept of approximate degradable channels by introducing $(\varepsilon ,\nu)$ –degradable channels. These are $\varepsilon $ –close in diamond norm and $\nu $ –close in completely bounded spectral norm to their complementary channel when composed with a degrading channel. This leads to improved upper bounds to the quantum- and private classical capacities of such channels. Moreover, these bounds can be further improved by considering certain unstabilized versions of the above norms. We show that upper bounds on the latter can be efficiently expressed as semidefinite programs. As an application, we obtain a new upper bound on the quantum capacity of the qubit depolarizing channel.
收紧熵的连续性约束和量子能力约束
熵的均匀连续性边界一般用概率分布或量子态之间的单一距离度量来表示,通常是总变异距离或痕量距离。然而,如果已知一个额外的距离度量,连续性约束就会大大加强。在这里,我们证明了香农熵在局部变化距离和总变化距离方面的紧密均匀连续性约束,从而使(Sason,2013 年)中的一个不等式更加尖锐。我们还从算子规范距离和迹距两方面得到了冯-诺依曼熵的均匀连续性约束。然后,我们应用我们的结果计算信道容量的上限。我们首先通过引入 $(\varepsilon ,\nu)$ 可降解通道来完善近似可降解通道的概念。当与降级信道组成时,这些信道与它们的互补信道在菱形规范上接近$\varepsilon $,在完全有界谱规范上接近$\nu $。这就改进了这类信道的量子容量和私有经典容量的上限。此外,考虑到上述规范的某些非稳定版本,这些界限还能得到进一步改进。我们证明,后者的上界可以有效地表示为半定式程序。作为一个应用,我们获得了量子位去极化信道量子容量的新上界。
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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CiteScore
8.20
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