Strong Converse Bounds for Compression of Mixed States

Abstract

In this paper, we study strong converse properties for both visible and blind compression of mixed states. The optimal rate of a visible compression scheme is obtained in terms of the entanglement of purification, whose additivity remains unknown so far. For a variation of extendible states, we prove that the entanglement of purification is additive and apply this to obtain a "pretty strong" converse bound for the blind and visible compression of such states. Namely, when the rate decreases below the optimal rate, the error exhibits a discontinuous jump from 0 to at least 132. To deal with the visible case for general states, we define a new quantity Eα,p(A:R) for a bipartite state AR and α ∈ (0,1) (1,∞) as the α-R\'enyi generalization of the entanglement of purification Ep(A:R). For α=1, we define E1,p(A:R):=Ep(A:R). We show that for any rate below the regularization α 1+Eα,p∞(A:R):=α 1+ n ∞ Eα,p(An:Rn) nn the fidelity for the visible compression exponentially converges to zero. Moreover, we consider blind compression of a general mixed-state source AR shared between an encoder and an inaccessible reference system R. We obtain a strong converse bound for the compression of this source by assuming that the decoder is a super-unital channel. This immediately implies a strong converse for the blind compression of ensembles of mixed states, by assuming a super-unital decoder, as this is a special case of the general mixed-state source AR where the reference system R has a classical structure.