English

Two dimensional RC/Subarray Constrained Codes: Bounded Weight and Almost Balanced Weight

Information Theory 2022-08-22 v1 math.IT

Abstract

In this work, we study two types of constraints on two-dimensional binary arrays. In particular, given p,ϵ>0p,\epsilon>0, we study (i) The pp-bounded constraint: a binary vector of size mm is said to be pp-bounded if its weight is at most pmpm, and (ii) The ϵ\epsilon-balanced constraint: a binary vector of size mm is said to be ϵ\epsilon-balanced if its weight is within [(0.5ϵ)m,(0.5+ϵ)m][(0.5-\epsilon)*m,(0.5+\epsilon)*m]. Such constraints are crucial in several data storage systems, those regard the information data as two-dimensional (2D) instead of one-dimensional (1D), such as the crossbar resistive memory arrays and the holographic data storage. In this work, efficient encoding/decoding algorithms are presented for binary arrays so that the weight constraint (either pp-bounded constraint or ϵ\epsilon-balanced constraint) is enforced over every row and every column, regarded as 2D row-column (RC) constrained codes; or over every subarray, regarded as 2D subarray constrained codes. While low-complexity designs have been proposed in the literature, mostly focusing on 2D RC constrained codes where p=1/2p = 1/2 and ϵ=0\epsilon = 0, this work provides efficient coding methods that work for both 2D RC constrained codes and 2D subarray constrained codes, and more importantly, the methods are applicable for arbitrary values of pp and ϵ\epsilon. Furthermore, for certain values of pp and ϵ\epsilon, we show that, for sufficiently large array size, there exists linear-time encoding/decoding algorithm that incurs at most one redundant bit.

Keywords

Cite

@article{arxiv.2208.09138,
  title  = {Two dimensional RC/Subarray Constrained Codes: Bounded Weight and Almost Balanced Weight},
  author = {Tuan Thanh Nguyen and Kui Cai and Han Mao Kiah and Kees A. Schouhamer Immink and Yeow Meng Chee},
  journal= {arXiv preprint arXiv:2208.09138},
  year   = {2022}
}
R2 v1 2026-06-25T01:48:45.381Z