Paper 2017/432
Statistical and Linear Independence of Binary Random Variables
Kaisa Nyberg
Abstract
Linear cryptanalysis makes use of statistical models that consider linear approximations over practical and ideal block ciphers as binary random variables. Recently, more complex models have been proposed that take also into account the statistical behavior of correlations of linear approximations over the key space of the cipher and over the randomness of the ideal cipher. The goal of this ongoing work is to investigate independence properties of linear approximations and their relationships. In this third revised version we show that the assumptions of Proposition~1 of the previous version are contradictory and hence renders that result useless. In particular, we prove that linear and statistical independence of binary random variables are equivalent properties in a vector space of variables if and only if all non-zero variables in this vector space are balanced, that is, correspond to components of a permutation. This study is motivated by finding reasonable wrong-key hypotheses for linear cryptanalysis and its generalizations which will also be discussed.
Note: This is an updated version of ongoing work.
Metadata
- Available format(s)
-
PDF
- Publication info
- Preprint.
- Keywords
- Xiao-Massey lemmablock cipherlinear cryptanalysislinear approximationrandom Boolean functionrandom vectorial Boolean functionmultidimensional linear cryptanalysiswrong-key hypothesis
- Contact author(s)
- kaisa nyberg @ aalto fi
- History
- 2018-01-30: last of 2 revisions
- 2017-05-22: received
- See all versions
- Short URL
- https://ia.cr/2017/432
- License
-
CC BY
BibTeX
@misc{cryptoeprint:2017/432,
author = {Kaisa Nyberg},
title = {Statistical and Linear Independence of Binary Random Variables},
howpublished = {Cryptology {ePrint} Archive, Paper 2017/432},
year = {2017},
url = {https://eprint.iacr.org/2017/432}
}
