Bilayer Low-Density Parity-Check Codes for Decode-and-Forward in Relay Channels

TL;DR

This paper introduces bilayer LDPC codes designed for relay channels, enabling efficient decode-and-forward relaying with near-capacity performance across various channel conditions.

Contribution

The paper proposes a novel bilayer LDPC code design and a bilayer density evolution analysis to approach the theoretical decode-and-forward rate in relay channels.

Findings

Achieves within 0.24 dB of Shannon limit for two channels simultaneously.

Finite-length codes approach within 0.6 dB of the theoretical rate at block length 10^5.

Applicable to relay networks with multiple relays.

Abstract

This paper describes an efficient implementation of binning for the relay channel using low-density parity-check (LDPC) codes. We devise bilayer LDPC codes to approach the theoretically promised rate of the decode-and-forward relaying strategy by incorporating relay-generated information bits in specially designed bilayer graphical code structures. While conventional LDPC codes are sensitively tuned to operate efficiently at a certain channel parameter, the proposed bilayer LDPC codes are capable of working at two different channel parameters and two different rates: that at the relay and at the destination. To analyze the performance of bilayer LDPC codes, bilayer density evolution is devised as an extension of the standard density evolution algorithm. Based on bilayer density evolution, a design methodology is developed for the bilayer codes in which the degree distribution is iteratively improved using linear programming. Further, in order to approach the theoretical decode-and-forward rate for a wide range of channel parameters, this paper proposes two different forms bilayer codes, the bilayer-expurgated and bilayer-lengthened codes. It is demonstrated that a properly designed bilayer LDPC code can achieve an asymptotic infinite-length threshold within 0.24 dB gap to the Shannon limits of two different channels simultaneously for a wide range of channel parameters. By practical code construction, finite-length bilayer codes are shown to be able to approach within a 0.6 dB gap to the theoretical decode-and-forward rate of the relay channel at a block length of $10^5$ and a bit-error probability (BER) of $10^{-4}$. Finally, it is demonstrated that a generalized version of the proposed bilayer code construction is applicable to relay networks with multiple relays.