Optimized Generalized LDPC Convolutional Codes

In this paper, some optimized encoding and decoding schemes are proposed for the generalized LDPC convolutional codes (GLDPC–CCs). In terms of the encoding scheme, a flexible doping method is proposed, which replaces multiple single parity check (SPC) nodes with one generalized check (GC) node. Diff...

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Bibliographic Details
Published in:Entropy (Basel, Switzerland) Vol. 27; no. 9; p. 930
Main Authors: Deng, Li, Tao, Kai, Shi, Zhiping, Zhang, You, Shi, Yinlong, Wang, Jian, Liu, Tian, Wang, Yongben
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 04.09.2025
Subjects:
adaptive weighting factor
Algorithms
Analysis
BCH codes
Chase–Pyndiah
Codes
Coding
Communication
Communications systems
Construction
Convolutional codes
Decoding
doping
Error correction & detection
generalized LDPC convolutional code
Hamming codes
hybrid layered normalized min-sum
low decoding complexity
Low density parity check codes
Nodes
Parity
Sums
Wave division multiplexing
doping
adaptive weighting factor
hybrid layered normalized min-sum
generalized LDPC convolutional code
Chase–Pyndiah
low decoding complexity
ISSN:1099-4300, 1099-4300
Online Access:Get full text
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Summary:In this paper, some optimized encoding and decoding schemes are proposed for the generalized LDPC convolutional codes (GLDPC–CCs). In terms of the encoding scheme, a flexible doping method is proposed, which replaces multiple single parity check (SPC) nodes with one generalized check (GC) node. Different types of BCH codes can be selected as the GC node by adjusting the number of SPC nodes to be replaced. Moreover, by fine-tuning the truncated bits and the extended parity check bits, or by reasonably adjusting the GC node distribution, the performance of GLDPC–CCs can be further improved. In terms of the decoding scheme, a hybrid layered normalized min-sum (HLNMS) decoding algorithm is proposed, where the layered normalized min-sum (LNMS) decoding is used for SPC nodes, and the Chase–Pyndiah decoding is adopted for GC nodes. Based on analysis of the decoding convergence of GC node and SPC node, an adaptive weight factor is designed for GC nodes that changes as the decoding iterations, aiming to further improve the decoding performance. In addition, an early stop decoding strategy is also proposed based on the minimum amplitude threshold of mutual information in order to reduce the decoding complexity. The simulation results have verified the superiority of the proposed scheme for GLDPC–CCs over the prior art, which has great application potential in optical communication systems.
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ISSN:1099-4300
1099-4300
DOI:10.3390/e27090930