A Framework of Variable-Length Source Encryption using Mutual Information Security Criterion: Universal Coding, Strong Converse Theorem
Abstract
In this paper we consider the variable-length lossless source coding for discrete memoryless sources. We proposes a new encryption framework for securely transmitting codewords over a noiseless channel. The proposed source encryption framework is based on the secure communication framework of the Shannon cipher system. In the proposed framework, we use the mutual information as a measure of information leakage to an adversary. We establish the necessary and sufficient condition for secure communication under the condition that the information leakage is upper bounded by a constant , thereby providing a complete solution to the problem. We also show that the obtained necessary and sufficient condition does not depend on the constant , demonstrating that we have the strong converse coding theorem for the proposed framework of source encryption. We further prove the existence of encryption/decryption schemes, which are universal in the sense that they work effectively for any distributions of the plain text and those of the key used for the encryption.
Cite
@article{arxiv.2605.06802,
title = {A Framework of Variable-Length Source Encryption using Mutual Information Security Criterion: Universal Coding, Strong Converse Theorem},
author = {Yasutada Oohama and Bagus Santoso},
journal= {arXiv preprint arXiv:2605.06802},
year = {2026}
}
Comments
7 pages, 5 figures. This is an extended version of the paper submitted for presentation in ISITA 2026, which will be held at Okinawa, Japan form November 1 to 4 in 2026. The submitted paper has several errors. We correct those errors in this arXiv paper. arXiv admin note: substantial text overlap with arXiv:2605.04720