A Neural Network Aided Approach for LDPC Coded DCO-OFDM with Clipping Distortion

TL;DR

This paper introduces a neural network-assisted receiver for LDPC coded DCO-OFDM systems that effectively mitigates clipping distortion, improving performance through a novel architecture and iterative decoding strategies.

Contribution

It proposes a neural network-based approach with a new stacked architecture for enhanced distortion mitigation in DCO-OFDM systems, incorporating iterative decoding with a priori probability integration.

Findings

Significant performance gains over traditional methods.

NN-BICM-ID outperforms NN-BICM across various schemes.

Effective distortion mitigation with reduced complexity.

Abstract

In this paper, a neural network-aided bit-interleaved coded modulation (NN-BICM) receiver is designed to mitigate the nonlinear clipping distortion in the LDPC coded direct currentbiased optical orthogonal frequency division multiplexing (DCOOFDM) systems. Taking the cross-entropy as loss function, a feed forward network is trained by backpropagation algorithm to output the condition probability through the softmax activation function, thereby assisting in a modified log-likelihood ratio (LLR) improvement. To reduce the complexity, this feed-forward network simplifies the input layer with a single symbol and the corresponding Gaussian variance instead of focusing on the inter-carrier interference between multiple subcarriers. On the basis of the neural network-aided BICM with Gray labelling, we propose a novel stacked network architecture of the bitinterleaved coded modulation with iterative decoding (NN-BICMID). Its performance has been improved further by calculating the condition probability with the aid of a priori probability that derived from the extrinsic LLRs in the LDPC decoder at the last iteration, at the expense of customizing neural network detectors at each iteration time separately. Utilizing the optimal DC bias as the midpoint of the dynamic region, the simulation results demonstrate that both the NN-BICM and NN-BICM-ID schemes achieve noticeable performance gains than other counterparts, in which the NN-BICM-ID clearly outperforms NN-BICM with various modulation and coding schemes.