Secure and Robust Identification via Classical-Quantum Channels
Abstract
We study the identification capacity of classical-quantum channels ("cq-channels"), under channel uncertainty and privacy constraints. To be precise, we consider first compound memoryless cq-channels and determine their identification capacity; then we add an eavesdropper, considering compound memoryless wiretap cqq-channels, and determine their secret identification capacity. In the first case (without privacy), we find the identification capacity always equal to the transmission capacity. In the second case, we find a dichotomy: either the secrecy capacity (also known as private capacity) of the channel is zero, and then also the secrecy identification capacity is zero, or the secrecy capacity is positive and then the secrecy identification capacity equals the transmission capacity of the main channel without the wiretapper. We perform the same analysis for the case of arbitrarily varying wiretap cqq-channels (cqq-AVWC), with analogous findings, and make several observations regarding the continuity and super-additivity of the identification capacity in the latter case.
Cite
@article{arxiv.1801.09967,
title = {Secure and Robust Identification via Classical-Quantum Channels},
author = {Holger Boche and Christian Deppe and Andreas Winter},
journal= {arXiv preprint arXiv:1801.09967},
year = {2020}
}
Comments
V2 with many corrections and improvements, 29 pages; v3 with additional clarifications and corrections, version accepted for IEEE Trans. Inf. Theory, 17 pages in ieeetran two-column format. A short version was presented at the 2018 Int's Symp. Inf. Theory: Proc. ISIT 2018 (18-22 June 2018, Vail CO), pp. 2674-2678