Wiretap channels with random states non-causally available at the encoder

Ziv Goldfeld; Paul Cuff; Haim H. Permuter

doi:10.1109/TIT.2019.2952389

Wiretap channels with random states non-causally available at the encoder

Ziv Goldfeld, Paul Cuff, Haim H. Permuter

Department of Electrical & Computer Engineering

Ben-Gurion University of the Negev

Research output: Contribution to journal › Article › peer-review

Abstract

We study the state-dependent (SD) wiretap channel (WTC) with non-causal channel state information (CSI) at the encoder. This model subsumes all instances of CSI availability as special cases, and calls for an efficient utilization of the state sequence for both reliability and security purposes. A lower bound on the secrecy-capacity, that improves upon the previously best known result published by Prabhakaran et al., is derived based on a novel superposition coding scheme. Our achievability gives rise to the exact secrecy-capacity characterization of a class of SD-WTCs that decompose into a product of two WTCs, one independent of the state and the other depends only on the state. The results are derived under the strict semantic-security metric that requires negligible information leakage for all message distributions.

Original language	American English
Article number	8894385
Pages (from-to)	1497-1519
Number of pages	23
Journal	IEEE Transactions on Information Theory
Volume	66
Issue number	3
DOIs	https://doi.org/10.1109/TIT.2019.2952389
State	Published - 1 Mar 2020

Keywords

Channel state information
Gelfand-Pinsker channel
semantic-security
soft-covering lemma
state-dependent channel
superposition code
wiretap channel

All Science Journal Classification (ASJC) codes

Information Systems
Computer Science Applications
Library and Information Sciences

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10.1109/TIT.2019.2952389

Cite this

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title = "Wiretap channels with random states non-causally available at the encoder",

abstract = "We study the state-dependent (SD) wiretap channel (WTC) with non-causal channel state information (CSI) at the encoder. This model subsumes all instances of CSI availability as special cases, and calls for an efficient utilization of the state sequence for both reliability and security purposes. A lower bound on the secrecy-capacity, that improves upon the previously best known result published by Prabhakaran et al., is derived based on a novel superposition coding scheme. Our achievability gives rise to the exact secrecy-capacity characterization of a class of SD-WTCs that decompose into a product of two WTCs, one independent of the state and the other depends only on the state. The results are derived under the strict semantic-security metric that requires negligible information leakage for all message distributions.",

keywords = "Channel state information, Gelfand-Pinsker channel, semantic-security, soft-covering lemma, state-dependent channel, superposition code, wiretap channel",

author = "Ziv Goldfeld and Paul Cuff and Permuter, \{Haim H.\}",

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Wiretap channels with random states non-causally available at the encoder

Abstract

Keywords

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