English

Rate-reliability tradeoff for deterministic identification

Information Theory 2025-07-29 v4 math.IT Quantum Physics

Abstract

We investigate deterministic identification over arbitrary memoryless channels under the constraint that the error probabilities of first and second kind are exponentially small in the block length n\mathbf{n}, controlled by reliability exponents E1,E20\mathbf{E_1,E_2 \geq 0}. In contrast to the regime of slowly vanishing errors, where the identifiable message length scales linearithmically as Θ(nlogn)\mathbf{\Theta(n\log n)}, here we find that for positive exponents linear scaling is restored, now with a rate that is a function of the reliability exponents. We give upper and lower bounds on the ensuing rate-reliability function in terms of (the logarithm of) the packing and covering numbers of the channel output set, which for small error exponents E1,E2>0\mathbf{E_1,E_2>0} can be expanded in leading order as the product of the Minkowski dimension of a certain parametrisation the channel output set and logmin{E1,E2}\mathbf{\log\min\{E_1,E_2\}}. These allow us to recover the previously observed slightly superlinear identification rates, and offer a different perspective for understanding them in more traditional information theory terms. We also show that even if only one of the two errors is required to be exponentially small, the linearithmic scaling is lost. We further illustrate our results with a discussion of the case of dimension zero, and extend them to classical-quantum channels and quantum channels with tensor product input restriction.

Keywords

Cite

@article{arxiv.2502.02389,
  title  = {Rate-reliability tradeoff for deterministic identification},
  author = {Pau Colomer and Christian Deppe and Holger Boche and Andreas Winter},
  journal= {arXiv preprint arXiv:2502.02389},
  year   = {2025}
}

Comments

16 pages, 2 figures. This paper has been accepted for publication at IEEE Transactions on Communications. A preliminary version of the present work was presented at the 2025 IEEE International Conference on Communications, Montreal QB, 8-12 June 2025

R2 v1 2026-06-28T21:32:14.670Z