Information Leakage in Zero-Error Source Coding: A Graph-Theoretic Perspective

Liu, Yucheng; Ong, Lawrence; Johnson, Sarah; Kliewer, Joerg; Sadeghi, Parastoo; Yeoh, Phee Lep

Title: Information Leakage in Zero-Error Source Coding: A Graph-Theoretic Perspective
Creator: Liu, Yucheng; Ong, Lawrence; Johnson, Sarah; Kliewer, Joerg; Sadeghi, Parastoo; Yeoh, Phee Lep
Relation: 2021 IEEE International Symposium on Information Theory. Proceedings of the 2021 IEEE International Symposium on Information Theory (Melbourne, VIC 12-20 July, 2021) p. 2590-2595
Publisher Link: http://dx.doi.org/10.1109/ISIT45174.2021.9517778
Publisher: Institute of Electrical and Electronics Engineers (IEEE)
Resource Type: conference paper
Date: 2021
Description: We study the information leakage to a guessing adversary in zero-error source coding. The source coding problem is defined by a confusion graph capturing the distinguishability between source symbols. The information leakage is measured by the ratio of the adversary's successful guessing probability after and before eavesdropping the codeword, maximized over all possible source distributions. Such measurement under the basic adversarial model where the adversary makes a single guess and the guess is regarded successful if and only if the estimator sequence equals to the true source sequence is known as the maximum min-entropy leakage or the maximal leakage in the literature. We develop a single-letter characterization of the optimal normalized leakage under the basic adversarial model, together with an optimum-achieving memoryless stochastic mapping scheme. An interesting observation is that the optimal normalized leakage is equal to the optimal compression rate with fixed-length source codes, both of which can be simultaneously achieved by some deterministic coding schemes. We then extend the leakage measurement to generalized adversarial models where the adversary makes multiple guesses and allows a certain level of distortion, for which we derive single-letter lower and upper bounds.
Subject: upper bound; source coding; stochastic processes; distortion; distortion measurement; eavesdropping
Identifier: http://hdl.handle.net/1959.13/1460924
Identifier: uon:46069
Identifier: ISBN:9781538682098
Language: eng
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