量子通信与经典信息的指数分离

Anurag Anshu, D. Touchette, Penghui Yao, Nengkun Yu
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引用次数: 11

摘要

我们展示了一个布尔函数,它的量子通信复杂度指数大于经典信息复杂度。另一个方向的指数分离已经从Kerenidis等人的工作中得知[SICOMP 44, pp. 1550-1572],因此我们的工作表明这两种复杂性度量是不可比较的。由于经典信息复杂度是量子信息复杂度的上界,而量子信息复杂度又等于平摊量子通信复杂度,因此我们的研究表明,对分布式量子通信复杂度的严密直接和结果是不成立的。我们用来表示这种分离的函数是Rao和Sinha [ECCC TR15-057]引入的对称k-ary指针跳跃函数,其经典通信复杂度指数大于其经典信息复杂度。在本文中,我们证明了该函数的量子通信复杂度多项式等价于它的经典通信复杂度。我们的证明背后的高级思想可以说是迄今为止最简单的信息和通信之间的指数分离,由一轮消去参数序列驱动,允许我们进一步简化Rao和Sinha的方法。作为我们开发的技术的另一个应用,给出了Alice和Bob通信之间最佳权衡的简单证明,即使允许预共享纠缠,同时计算n位上的相关大于大于函数:假设Bob最多通信b位,那么Alice必须向Bob发送n/2O (b)位。我们还提出了一个经典协议来实现这个边界。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Exponential separation of quantum communication and classical information
We exhibit a Boolean function for which the quantum communication complexity is exponentially larger than the classical information complexity. An exponential separation in the other direction was already known from the work of Kerenidis et. al. [SICOMP 44, pp. 1550-1572], hence our work implies that these two complexity measures are incomparable. As classical information complexity is an upper bound on quantum information complexity, which in turn is equal to amortized quantum communication complexity, our work implies that a tight direct sum result for distributional quantum communication complexity cannot hold. The function we use to present such a separation is the Symmetric k-ary Pointer Jumping function introduced by Rao and Sinha [ECCC TR15-057], whose classical communication complexity is exponentially larger than its classical information complexity. In this paper, we show that the quantum communication complexity of this function is polynomially equivalent to its classical communication complexity. The high-level idea behind our proof is arguably the simplest so far for such an exponential separation between information and communication, driven by a sequence of round-elimination arguments, allowing us to simplify further the approach of Rao and Sinha. As another application of the techniques that we develop, a simple proof for an optimal trade-off between Alice's and Bob's communication is given, even when allowing pre-shared entanglement, while computing the related Greater-Than function on n bits: say Bob communicates at most b bits, then Alice must send n/2O (b) bits to Bob. We also present a classical protocol achieving this bound.
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