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Diskretnaya Matematika, 2016, Volume 28, Issue 1, Pages 19–43
DOI: https://doi.org/10.4213/dm1356
(Mi dm1356)
 

This article is cited in 4 scientific papers (total in 4 papers)

Steganographic capacity for one-dimensional Markov cover} \runningtitle{Steganographic capacity for one-dimensional Markov cover} \author*[1]{Valeriy A. Voloshko} \runningauthor{V. A. Voloshko} \affil[1]{ Belarusian State University, e-mail: valeravoloshko@yandex.ru} \abstract{For shift-invariant probability measures on the set of infinite two-sided binary sequences (one-dimensional covers) we introduce the notion of capacity as a maximum portion of embedded into the cover uniformly distributed (purely random) binary sequence (message) that admits special correction of the cover restoring its distribution up to distribution of $n$-tuples (subwords of some fixed length $n$). “Special correction” is carried out using the proposed new algorithm that changes some of the cover's symbols not occupied by embedded message. The features of the introduced capacity are examined for the Markov cover. In particular, we show how capacity may be significantly increased by weakening of the standard constraint that positions for message embedding have to be chosen by independent unfair coin tosses. Experimental results are presented for correction of real steganographic covers after LSB-embedding.} \keywords{binary sequence, shift-invariant measure, steganography, capacity

V. A. Voloshko

Research Institute of Applied Problems of Mathematics and Informatics, Belarusian State University, Minsk
References:
Abstract: For shift-invariant probability measures on the set of infinite two-sided binary sequences (one-dimensional covers) we introduce the notion of capacity as a maximum portion of embedded into the cover uniformly distributed (purely random) binary sequence (message) that admits special correction of the cover restoring its distribution up to distribution of $n$-tuples (subwords of some fixed length $n$). “Special correction” is carried out using the proposed new algorithm that changes some of the cover's symbols not occupied by embedded message. The features of the introduced capacity are examined for the Markov cover. In particular, we show how capacity may be significantly increased by weakening of the standard constraint that positions for message embedding have to be chosen by independent unfair coin tosses. Experimental results are presented for correction of real steganographic covers after LSB-embedding.} \keywords{binary sequence, shift-invariant measure, steganography, capacity
Keywords: binary sequence, shift-invariant measure, steganography, capacity.
Received: 31.03.2015
English version:
Discrete Mathematics and Applications, 2017, Volume 27, Issue 4, Pages 247–268
DOI: https://doi.org/10.1515/dma-2017-0026
Bibliographic databases:
Document Type: Article
UDC: 519.719.2
Language: Russian
Citation: V. A. Voloshko, “Steganographic capacity for one-dimensional Markov cover} \runningtitle{Steganographic capacity for one-dimensional Markov cover} \author*[1]{Valeriy A. Voloshko} \runningauthor{V. A. Voloshko} \affil[1]{ Belarusian State University, e-mail: valeravoloshko@yandex.ru} \abstract{For shift-invariant probability measures on the set of infinite two-sided binary sequences (one-dimensional covers) we introduce the notion of capacity as a maximum portion of embedded into the cover uniformly distributed (purely random) binary sequence (message) that admits special correction of the cover restoring its distribution up to distribution of $n$-tuples (subwords of some fixed length $n$). “Special correction” is carried out using the proposed new algorithm that changes some of the cover's symbols not occupied by embedded message. The features of the introduced capacity are examined for the Markov cover. In particular, we show how capacity may be significantly increased by weakening of the standard constraint that positions for message embedding have to be chosen by independent unfair coin tosses. Experimental results are presented for correction of real steganographic covers after LSB-embedding.} \keywords{binary sequence, shift-invariant measure, steganography, capacity”, Diskr. Mat., 28:1 (2016), 19–43; Discrete Math. Appl., 27:4 (2017), 247–268
Citation in format AMSBIB
\Bibitem{Vol16}
\by V.~A.~Voloshko
\paper Steganographic capacity for one-dimensional Markov cover} \runningtitle{Steganographic capacity for one-dimensional Markov cover} \author*[1]{Valeriy A. Voloshko} \runningauthor{V.\,A. Voloshko} \affil[1]{ Belarusian State University, e-mail: valeravoloshko@yandex.ru} \abstract{For shift-invariant probability measures on the set of infinite two-sided binary sequences (one-dimensional covers) we introduce the notion of capacity as a maximum portion of embedded into the cover uniformly distributed (purely random) binary sequence (message) that admits special correction of the cover restoring its distribution up to distribution of $n$-tuples (subwords of some fixed length $n$). ``Special correction'' is carried out using the proposed new algorithm that changes some of the cover's symbols not occupied by embedded message. The features of the introduced capacity are examined for the Markov cover. In particular, we show how capacity may be significantly increased by weakening of the standard constraint that positions for message embedding have to be chosen by independent unfair coin tosses. Experimental results are presented for correction of real steganographic covers after LSB-embedding.} \keywords{binary sequence, shift-invariant measure, steganography, capacity
\jour Diskr. Mat.
\yr 2016
\vol 28
\issue 1
\pages 19--43
\mathnet{http://mi.mathnet.ru/dm1356}
\crossref{https://doi.org/10.4213/dm1356}
\mathscinet{http://mathscinet.ams.org/mathscinet-getitem?mr=3527007}
\elib{https://elibrary.ru/item.asp?id=25707491}
\transl
\jour Discrete Math. Appl.
\yr 2017
\vol 27
\issue 4
\pages 247--268
\crossref{https://doi.org/10.1515/dma-2017-0026}
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\scopus{https://www.scopus.com/record/display.url?origin=inward&eid=2-s2.0-85028071395}
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  • https://doi.org/10.4213/dm1356
  • https://www.mathnet.ru/eng/dm/v28/i1/p19
  • This publication is cited in the following 4 articles:
    Citing articles in Google Scholar: Russian citations, English citations
    Related articles in Google Scholar: Russian articles, English articles
    Дискретная математика
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