A new quantum version of f-divergence

Abstract

This paper proposes and studies new quantum version of f-divergences, a class of convex functionals of a pair of probability distributions including Kullback-Leibler divergence, Rnyi-type relative entropy and so on. There are several quantum versions so far, including the one by Petz. We introduce another quantum version (Df, below), defined as the solution to an optimization problem, or the minimum classical f- divergence necessary to generate a given pair of quantum states. It turns out to be the largest quantum f-divergence. The closed formula of Df is given either if f is operator convex, or if one of the state is a pure state. Also, concise representation of Df as a pointwise supremum of linear functionals is given and used for the clarification of various properties of the quality. Using the closed formula of Df, we show: Suppose f is operator convex. Then the\ maximum f\,- divergence of the probability distributions of a measurement under the state and σ is strictly less than Df( σ) . This statement may seem intuitively trivial, but when f is not operator convex, this is not always true. A counter example is f( λ) = 1-λ , which corresponds to total variation distance. We mostly work on finite dimensional Hilbert space, but some results are extended to infinite dimensional case.