English

Entanglement cost and quantum channel simulation

Quantum Physics 2023-01-18 v3 Information Theory math.IT

Abstract

This paper proposes a revised definition for the entanglement cost of a quantum channel N\mathcal{N}. In particular, it is defined here to be the smallest rate at which entanglement is required, in addition to free classical communication, in order to simulate nn calls to N\mathcal{N}, such that the most general discriminator cannot distinguish the nn calls to N\mathcal{N} from the simulation. The most general discriminator is one who tests the channels in a sequential manner, one after the other, and this discriminator is known as a quantum tester [Chiribella et al., Phys. Rev. Lett., 101, 060401 (2008)] or one who is implementing a quantum co-strategy [Gutoski et al., Symp. Th. Comp., 565 (2007)]. As such, the proposed revised definition of entanglement cost of a quantum channel leads to a rate that cannot be smaller than the previous notion of a channel's entanglement cost [Berta et al., IEEE Trans. Inf. Theory, 59, 6779 (2013)], in which the discriminator is limited to distinguishing parallel uses of the channel from the simulation. Under this revised notion, I prove that the entanglement cost of certain teleportation-simulable channels is equal to the entanglement cost of their underlying resource states. Then I find single-letter formulas for the entanglement cost of some fundamental channel models, including dephasing, erasure, three-dimensional Werner--Holevo channels, epolarizing channels (complements of depolarizing channels), as well as single-mode pure-loss and pure-amplifier bosonic Gaussian channels. These examples demonstrate that the resource theory of entanglement for quantum channels is not reversible. Finally, I discuss how to generalize the basic notions to arbitrary resource theories.

Keywords

Cite

@article{arxiv.1807.11939,
  title  = {Entanglement cost and quantum channel simulation},
  author = {Mark M. Wilde},
  journal= {arXiv preprint arXiv:1807.11939},
  year   = {2023}
}

Comments

28 pages, 7 figures

R2 v1 2026-06-23T03:20:42.269Z