Design of Spatially Coupled LDPC Codes over GF(q) for Windowed Decoding

TL;DR

This paper extends spatially coupled LDPC codes to GF(q), demonstrating that windowed decoding offers near-capacity thresholds with reduced latency and complexity, especially as the finite field size increases, over BEC and BIAWGNC channels.

Contribution

The paper introduces design rules for q-ary SC-LDPC codes with windowed decoding, showing significant threshold improvements and complexity reductions compared to binary codes.

Findings

Windowed decoding of q-ary SC-LDPC codes achieves near-capacity thresholds.

Threshold gains increase with larger finite field size q.

Decoding complexity and latency are significantly reduced with windowed decoding.

Abstract

In this paper we consider the generalization of binary spatially coupled low-density parity-check (SC-LDPC) codes to finite fields GF$(q)$, $q\geq 2$, and develop design rules for $q$-ary SC-LDPC code ensembles based on their iterative belief propagation (BP) decoding thresholds, with particular emphasis on low-latency windowed decoding (WD). We consider transmission over both the binary erasure channel (BEC) and the binary-input additive white Gaussian noise channel (BIAWGNC) and present results for a variety of $(J,K)$-regular SC-LDPC code ensembles constructed over GF$(q)$ using protographs. Thresholds are calculated using protograph versions of $q$-ary density evolution (for the BEC) and $q$-ary extrinsic information transfer analysis (for the BIAWGNC). We show that WD of $q$-ary SC-LDPC codes provides significant threshold gains compared to corresponding (uncoupled) $q$-ary LDPC block code (LDPC-BC) ensembles when the window size $W$ is large enough and that these gains increase as the finite field size $q=2^m$ increases. Moreover, we demonstrate that the new design rules provide WD thresholds that are close to capacity, even when both $m$ and $W$ are relatively small (thereby reducing decoding complexity and latency). The analysis further shows that, compared to standard flooding-schedule decoding, WD of $q$-ary SC-LDPC code ensembles results in significant reductions in both decoding complexity and decoding latency, and that these reductions increase as $m$ increases. For applications with a near-threshold performance requirement and a constraint on decoding latency, we show that using $q$-ary SC-LDPC code ensembles, with moderate $q>2$, instead of their binary counterparts results in reduced decoding complexity.