Kalla Sai-Chandra-Kumari, Gagné Christian, Zeng Ming, Rusch Leslie A
Opt Express. 2021 Apr 26;29(9):13033-13047. doi: 10.1364/OE.423103.
We explore recurrent and feedforward neural networks to mitigate severe inter-symbol interference (ISI) caused by bandlimited channels, such as high speed optical communications systems pushing the frequency response of transmitter components. We propose a novel deep bidirectional long short-term memory (BiLSTM) architecture that strongly emphasizes dependencies in data sequences. For the first time, we demonstrate via simulation that for QPSK transmission the deep BiLSTM achieves the optimal bit error rate performance of a maximum likelihood sequence estimator (MLSE) with perfect channel knowledge. We assess performance for a variety of channels exhibiting ISI, including an optical channel at 100 Gbaud operation using a 35 GHz silicon photonic (SiP) modulator. We show how the neural network performance deteriorates with increasing modulation order and ISI severity. While no longer achieving MLSE performance, the deep BiLSTM greatly outperforms linear equalization in these cases. More importantly, the neural network requires no channel state information, while its performance is comparable to conventional equalizers with perfect channel knowledge.
我们探索递归神经网络和前馈神经网络,以减轻由带宽受限信道(如推动发射机组件频率响应的高速光通信系统)引起的严重符号间干扰(ISI)。我们提出了一种新颖的深度双向长短期记忆(BiLSTM)架构,该架构强烈强调数据序列中的依赖性。首次通过仿真证明,对于QPSK传输,深度BiLSTM在具有完美信道知识的情况下实现了最大似然序列估计器(MLSE)的最优误码率性能。我们评估了各种呈现ISI的信道的性能,包括使用35 GHz硅光子(SiP)调制器在100 Gbaud速率下运行的光信道。我们展示了神经网络性能如何随着调制阶数和ISI严重性的增加而恶化。虽然不再能达到MLSE性能,但在这些情况下,深度BiLSTM大大优于线性均衡。更重要的是,神经网络不需要信道状态信息,而其性能与具有完美信道知识的传统均衡器相当。
