Singleton Bounds for Entanglement-Assisted Classical and Quantum Error Correcting Codes
Abstract
We show that entirely quantum Shannon theoretic methods, based on von Neumann entropies and their properties, can be used to derive Singleton bounds on the performance of entanglement-assisted hybrid classical-quantum (EACQ) error correcting codes. Concretely, we show that the triple-rate region of qubits, cbits and ebits of possible EACQ codes over arbitrary alphabet sizes is contained in the quantum Shannon theoretic rate region of an associated memoryless erasure channel, which turns out to be a polytope. We show that a large part of this region is attainable by certain EACQ codes, whenever the local alphabet size (i.e. Hilbert space dimension) is large enough, in keeping with known facts about classical and quantum minimum distance separable (MDS) codes: in particular, all of its extreme points and all but one of its extremal lines. The attainability of the remaining one extremal line segment is left as an open question.
Keywords
Cite
@article{arxiv.2202.02184,
title = {Singleton Bounds for Entanglement-Assisted Classical and Quantum Error Correcting Codes},
author = {Manideep Mamindlapally and Andreas Winter},
journal= {arXiv preprint arXiv:2202.02184},
year = {2024}
}
Comments
18 pages, 1 figure; v2 has more details, more references, and self-contained proofs; in v3 some typos are fixed and ORCIDs added; v4 greatly expanded to 22 pages with more references, now 4 figures, improvements to the presentation