Classical Information Storage in an n-Level Quantum System

Frenkel, Péter Ernő

Weiner, Mihály

2015

QA Mathematics / matematika

QA71 Number theory / számelmélet

QA72 Algebra / algebra

A game is played by a team of two—say Alice and Bob—in which the value of a random variable x is revealed to Alice only, who cannot freely communicate with Bob. Instead, she is given a quantum n-level system, respectively a classical n-state system, which she can put in possession of Bob in any state she wishes. We evaluate how successfully they managed to store and recover the value of x by requiring Bob to specify a value z and giving a reward of value f (x,z) to the team. We show that whatever the probability distribution of x and the reward function f are, when using a quantum n-level system, the maximum expected reward obtainable with the best possible team strategy is equal to that obtainable with the use of a classical n-state system. The proof relies on mixed discriminants of positive matrices and—perhaps surprisingly—an application of the Supply–Demand Theorem for bipartite graphs. As a corollary, we get an infinite set of new, dimension dependent inequalities regarding positive operator valued measures and density operators on complex n-space. As a further corollary, we see that the greatest value, with respect to a given distribution of x, of the mutual information I (x; z) that is obtainable using an n-level quantum system equals the analogous maximum for a classical n-state system. © 2015, Springer-Verlag Berlin Heidelberg.

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http://real.mtak.hu/33623/1/1304.5723v3.pdf

Frenkel, Péter Ernő and Weiner, Mihály (2015) Classical Information Storage in an n-Level Quantum System. COMMUNICATIONS IN MATHEMATICAL PHYSICS, 340 (2). pp. 563-574. ISSN 0010-3616

http://dx.doi.org/10.1007/s00220-015-2463-0

http://real.mtak.hu/33623/