English

On the $k$-error linear complexity for $p^n$-periodic binary sequences via hypercube theory

Cryptography and Security 2014-08-13 v2

Abstract

The linear complexity and the kk-error linear complexity of a binary sequence are important security measures for key stream strength. By studying binary sequences with the minimum Hamming weight, a new tool named as hypercube theory is developed for pnp^n-periodic binary sequences. In fact, hypercube theory is based on a typical sequence decomposition and it is a very important tool in investigating the critical error linear complexity spectrum proposed by Etzion et al. To demonstrate the importance of hypercube theory, we first give a standard hypercube decomposition based on a well-known algorithm for computing linear complexity and show that the linear complexity of the first hypercube in the decomposition is equal to the linear complexity of the original sequence. Second, based on such decomposition, we give a complete characterization for the first decrease of the linear complexity for a pnp^n-periodic binary sequence ss. This significantly improves the current existing results in literature. As to the importance of the hypercube, we finally derive a counting formula for the mm-hypercubes with the same linear complexity.

Keywords

Cite

@article{arxiv.1402.5472,
  title  = {On the $k$-error linear complexity for $p^n$-periodic binary sequences via hypercube theory},
  author = {Jianqin Zhou and Wanquan Liu and Guanglu Zhou},
  journal= {arXiv preprint arXiv:1402.5472},
  year   = {2014}
}

Comments

16 pages. arXiv admin note: substantial text overlap with arXiv:1309.1829, arXiv:1312.6927

R2 v1 2026-06-22T03:13:33.742Z