A simplified convolutional neural network is inserted as a function node in the sum-product algorithm factor graph for FTN signaling to model residual ISI, with modified message updates enabling turbo equalization and up to 2.5 dB BER gain.
On Deep Learning-Based Channel Decoding
1 Pith paper cite this work. Polarity classification is still indexing.
abstract
We revisit the idea of using deep neural networks for one-shot decoding of random and structured codes, such as polar codes. Although it is possible to achieve maximum a posteriori (MAP) bit error rate (BER) performance for both code families and for short codeword lengths, we observe that (i) structured codes are easier to learn and (ii) the neural network is able to generalize to codewords that it has never seen during training for structured, but not for random codes. These results provide some evidence that neural networks can learn a form of decoding algorithm, rather than only a simple classifier. We introduce the metric normalized validation error (NVE) in order to further investigate the potential and limitations of deep learning-based decoding with respect to performance and complexity.
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cs.IT 1years
2019 1verdicts
UNVERDICTED 1representative citing papers
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Deep Learning Assisted Sum-Product Detection Algorithm for Faster-than-Nyquist Signaling
A simplified convolutional neural network is inserted as a function node in the sum-product algorithm factor graph for FTN signaling to model residual ISI, with modified message updates enabling turbo equalization and up to 2.5 dB BER gain.