Matching graph connectivity of LDPC codes to high-order modulation by bit interleaving

The decoding threshold and the error floor are two key performance metrics that are commonly used to evaluate the goodness of a LDPC code design. For a finite-length irregular LDPC code employing sub-optimal iterative decoding algorithm, the major factors that determine the decoding threshold and th...

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Bibliographic Details
Published in2008 46th Annual Allerton Conference on Communication, Control, and Computing pp. 1059 - 1064
Main Authors Jing Lei, Wen Gao
Format Conference Proceeding
LanguageEnglish
Published IEEE 01.09.2008
Subjects
Code standards
Digital video broadcasting
Interleaved codes
Iterative algorithms
Iterative decoding
Measurement
Modulation coding
Parity check codes
Protection
Standards development
Online AccessGet full text
ISBN1424429250
9781424429257
DOI10.1109/ALLERTON.2008.4797676

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Summary:The decoding threshold and the error floor are two key performance metrics that are commonly used to evaluate the goodness of a LDPC code design. For a finite-length irregular LDPC code employing sub-optimal iterative decoding algorithm, the major factors that determine the decoding threshold and the error floor are nodes degree distribution as well as the edge permutation associated with its tanner graph. In addition, due to the non-uniform bitwise error protection inherent to a high-order constellation (e.g. 256-QAM, 1024-QAM), generally there exists a mismatch between the encoder and the modulator unless a dedicated ldquoouterrdquo bit interleaver (de-multiplexer) is plugged between the two modules to match the non-uniform bits reliability. Motivated by the requirement for high spectral efficiency in the development of future DVB-C standard as well as the industrial trend for reusing the LDPC codes standardized in DVB-S2 specification, in this paper we focus on the design of the ldquoouterrdquo bit interleaver, assuming the LDPC code and the order 2 2Q constellation mapper are fixed a priori. The configuration for the proposed bit interleaver is solved by optimizing the degree profiles of Q ldquosubcodesrdquo, subject to the constraints of the degree distribution given by the ldquomotherrdquo code. Besides, to prevent the error-prone patterns existing in the ldquomotherrdquo code to cause decoding failures, an extra constraint is imposed on the allocation of low-degree coded bits to the constellation mapper. Compared with the random interleaving approach, the proposed bit interleaver can achieve significant gains in both the waterfall and the error floor regions.
ISBN:1424429250
9781424429257
DOI:10.1109/ALLERTON.2008.4797676