Related papers: Neural Window Decoder for SC-LDPC Codes

Neural Window Decoder for SC-LDPC Codes

URL: http://arxiv.org/abs/2411.19092v1
Date: Thu, 28 Nov 2024 12:13:29 GMT
Title: Neural Window Decoder for SC-LDPC Codes
Authors: Dae-Young Yun, Hee-Youl Kwak, Yongjune Kim, Sang-Hyo Kim, Jong-Seon No,
Abstract summary: We propose a neural window decoder (NWD) for spatially coupled low-density parity-check (SC-LDPC) codes. To train the weights of NWD, we introduce two novel training strategies. We also address the error propagation problem inherent in SC-LDPC codes by deploying a complementary weight set.
Score: 15.190674451882964
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Abstract: In this paper, we propose a neural window decoder (NWD) for spatially coupled low-density parity-check (SC-LDPC) codes. The proposed NWD retains the conventional window decoder (WD) process but incorporates trainable neural weights. To train the weights of NWD, we introduce two novel training strategies. First, we restrict the loss function to target variable nodes (VNs) of the window, which prunes the neural network and accordingly enhances training efficiency. Second, we employ the active learning technique with a normalized loss term to prevent the training process from biasing toward specific training regions. Next, we develop a systematic method to derive non-uniform schedules for the NWD based on the training results. We introduce trainable damping factors that reflect the relative importance of check node (CN) updates. By skipping updates with less importance, we can omit $\mathbf{41\%}$ of CN updates without performance degradation compared to the conventional WD. Lastly, we address the error propagation problem inherent in SC-LDPC codes by deploying a complementary weight set, which is activated when an error is detected in the previous window. This adaptive decoding strategy effectively mitigates error propagation without requiring modifications to the code and decoder structures.

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