We evaluate improvement in the performance of the optical transmission systems operating with the continuous nonlinear Fourier spectrum by the artificial neural network equalisers installed at the receiver end. We propose here a novel equaliser designs based on bidirectional long short-term memory (BLSTM) gated recurrent neural network and compare their performance with the equaliser based on several fully connected layers. The proposed approach accounts for the correlations between different nonlinear spectral components. The application of BLSTM equaliser leads to a 16x improvement in terms of bit-error rate (BER) compared to the non-equalised case. The proposed equaliser makes it possible to reach the data rate of 170 Gbit/s for one pola...
We investigate methods for experimental performance enhancement of auto-encoders based on a recurren...
In this work, we demonstrate the offline FPGA realization of both recurrent and feedforward neural n...
We present the results of the comparative performance-versus-complexity analysis for the several typ...
We evaluate improvement in the performance of the optical transmission systems operating with the co...
We propose a novel low-complexity artificial neural network (ANN)-based nonlinear equalizer (NLE) fo...
In this paper we investigate the application of dynamic multi-leyer perceptron networks for long hau...
We investigate the application of dynamic deep neural networks for nonlinear equalization in long ha...
The computational complexity and system bit-error-rate (BER) performance of four types of neural-net...
In this work, we address the question of the adaptability of artificial neural networks (NNs) used f...
Nonlinear distortion has always been a challenge for optical communication due to the nonlinear tra...
We propose a method to improve the performance of the nonlinear Fourier transform (NFT)-based optica...
In this work, we demonstrate the offline FPGA realization of both recurrent and feedforward neural n...
The impairments arising from the Kerr nonlinearity in optical fibers limit the achievable informatio...
We propose an efficient neural-network-based equalization jointly compensating fiber and transceiver...
We investigate methods for experimental performance enhancement of auto-encoders based on a recurren...
In this work, we demonstrate the offline FPGA realization of both recurrent and feedforward neural n...
We present the results of the comparative performance-versus-complexity analysis for the several typ...
We evaluate improvement in the performance of the optical transmission systems operating with the co...
We propose a novel low-complexity artificial neural network (ANN)-based nonlinear equalizer (NLE) fo...
In this paper we investigate the application of dynamic multi-leyer perceptron networks for long hau...
We investigate the application of dynamic deep neural networks for nonlinear equalization in long ha...
The computational complexity and system bit-error-rate (BER) performance of four types of neural-net...
In this work, we address the question of the adaptability of artificial neural networks (NNs) used f...
Nonlinear distortion has always been a challenge for optical communication due to the nonlinear tra...
We propose a method to improve the performance of the nonlinear Fourier transform (NFT)-based optica...
In this work, we demonstrate the offline FPGA realization of both recurrent and feedforward neural n...
The impairments arising from the Kerr nonlinearity in optical fibers limit the achievable informatio...
We propose an efficient neural-network-based equalization jointly compensating fiber and transceiver...
We investigate methods for experimental performance enhancement of auto-encoders based on a recurren...
In this work, we demonstrate the offline FPGA realization of both recurrent and feedforward neural n...
We present the results of the comparative performance-versus-complexity analysis for the several typ...