On the $k$-error linear complexity for $2^n$-periodic binary sequences via Cube Theory
Abstract
The linear complexity and k-error linear complexity of a sequence have been used as important measures of keystream strength, hence designing a sequence with high linear complexity and -error linear complexity is a popular research topic in cryptography. In this paper, the concept of stable -error linear complexity is proposed to study sequences with stable and large -error linear complexity. In order to study k-error linear complexity of binary sequences with period , a new tool called cube theory is developed. By using the cube theory, one can easily construct sequences with the maximum stable -error linear complexity. For such purpose, we first prove that a binary sequence with period can be decomposed into some disjoint cubes and further give a general decomposition approach. Second, it is proved that the maximum -error linear complexity is over all -periodic binary sequences, where . Thirdly, a characterization is presented about the th () decrease in the -error linear complexity for a -periodic binary sequence and this is a continuation of Kurosawa et al. recent work for the first decrease of k-error linear complexity. Finally, A counting formula for -cubes with the same linear complexity is derived, which is equivalent to the counting formula for -error vectors. The counting formula of -periodic binary sequences which can be decomposed into more than one cube is also investigated, which extends an important result by Etzion et al..
Keywords
Cite
@article{arxiv.1309.1829,
title = {On the $k$-error linear complexity for $2^n$-periodic binary sequences via Cube Theory},
author = {Jianqin Zhou and Wanquan Liu},
journal= {arXiv preprint arXiv:1309.1829},
year = {2013}
}
Comments
11 pages. arXiv admin note: substantial text overlap with arXiv:1109.4455, arXiv:1108.5793, arXiv:1112.6047