English

Identification Over Noisy Permutation Channels

Information Theory 2025-06-18 v2 math.IT

Abstract

We study message identification over the noisy permutation channel. For discrete memoryless channels (DMCs), the number of identifiable messages grows doubly exponentially, and the maximum second-order exponent is same as the Shannon capacity of the DMC. We consider a qq-ary noisy permutation channel where the transmitted vector is first permuted by a permutation chosen uniformly at random, and then passed through a DMC with strictly positive entries in its transition probability matrix UU. In an earlier work, we showed that over qq-ary noiseless permutation channel, 2cnnq12^{c_n n^{q-1}} messages can be identified if cn0c_n\rightarrow 0, and a strong converse holds for 2cnnq12^{c_n n^{q-1}} messages if cnc_n\rightarrow \infty. For the qq-ary noisy permutation channel, we show that message sizes growing as 2Rn(nlogn)(r1)/22^{R_n \left( \frac{n}{\log n}\right)^{(r-1)/2}}, where rr be the rank of UU, are identifiable for any Rn0R_n\rightarrow 0. We also prove a strong converse result showing that for any sequence of identification codes with 2(Rnn(q1)/2(logn)1+(q1)(q2)2),2^{\left(R_n n^{(q-1)/2}(\log n)^{1+\frac{(q-1)(q-2)}{2}}\right)}, messages, where RnR_n \rightarrow \infty, the sum of Type-I and Type-II error probabilities approaches at least 11 as nn\rightarrow \infty. Our converse proof uses the idea of channel resolvability. We propose a novel deterministic quantization scheme for quantization of a distribution over the set of all compositions/types by an MM-type input distribution when the distortion is measured on the output distribution in total variation distance. This plays a key role in the converse proof. We have also studied identification with deterministic encoder and decoder, and proved tight achievability, weak converse, and strong converse.

Keywords

Cite

@article{arxiv.2412.11091,
  title  = {Identification Over Noisy Permutation Channels},
  author = {Abhishek Sarkar and Bikash Kumar Dey},
  journal= {arXiv preprint arXiv:2412.11091},
  year   = {2025}
}

Comments

52 pages

R2 v1 2026-06-28T20:35:40.625Z