On the Minimum/Stopping Distance of Array Low-Density Parity-Check Codes

TL;DR

This paper investigates the minimum and stopping distances of array LDPC codes, providing improved bounds for certain parameters and new specific results for codes with small to moderate q values.

Contribution

It introduces new upper bounds for the minimum distance of array LDPC codes for m=6 and m=7, improving previous bounds and offering specific results for q up to 79.

Findings

Improved upper bound for d(q,6) to 20

New upper bound for d(q,7) to 24

Specific minimum/stopping distance results for q ≤ 79

Abstract

In this work, we study the minimum/stopping distance of array low-density parity-check (LDPC) codes. An array LDPC code is a quasi-cyclic LDPC code specified by two integers q and m, where q is an odd prime and m <= q. In the literature, the minimum/stopping distance of these codes (denoted by d(q,m) and h(q,m), respectively) has been thoroughly studied for m <= 5. Both exact results, for small values of q and m, and general (i.e., independent of q) bounds have been established. For m=6, the best known minimum distance upper bound, derived by Mittelholzer (IEEE Int. Symp. Inf. Theory, Jun./Jul. 2002), is d(q,6) <= 32. In this work, we derive an improved upper bound of d(q,6) <= 20 and a new upper bound d(q,7) <= 24 by using the concept of a template support matrix of a codeword/stopping set. The bounds are tight with high probability in the sense that we have not been able to find codewords of strictly lower weight for several values of q using a minimum distance probabilistic algorithm. Finally, we provide new specific minimum/stopping distance results for m <= 7 and low-to-moderate values of q <= 79.