We present a machine learning (ML) framework for designing desired signal power profiles over the spectral and spatial domains in the fiber span. The proposed framework adjusts the Raman pump power values to obtain the desired two-dimensional (2D) profiles using a convolutional neural network (CNN) followed by the differential evolution (DE) technique. The CNN learns the mapping between the 2D profiles and their corresponding pump power values using a data-set generated by exciting the amplification setup. Nonetheless, its performance is not accurate for designing 2D profiles of practical interest, such as a 2D flat or a 2D symmetric (with respect to the middle point in distance). To adjust the pump power values more accurately, the DE fine...
We introduce a load aware machine learning method for prediction of Raman gain profiles. It enables ...
Two artificial neural network (ANN) models are presented to predict power profiles over C+L–band in ...
The paper presents recent advances in the design of controllable, highly accurate, and multi-band Ra...
We experimentally validate a real-time machine learning framework, capable of controlling the pump p...
We propose a Convolutional Neural Network (CNN) to learn the mapping between the 2D power profiles, ...
A machine learning technique was recently proposed to optimize the gain of a multi-pump single-mode...
Optical communication systems are always evolving to support the need for ever-increasing transmissi...
A multi-layer neural network is employed to learn the mapping between Raman gain profile and pump po...
It has been recently demonstrated that neural networks can learn the complex pump–signal relations i...
A machine learning framework for Raman amplifier design is experimentally tested. Performance in ter...
A machine learning framework predicting pump powers and noise figure profile for a target distribute...
One of the most promising solutions to overcome the capacity limit of current optical fiber links i...
A wide range of highly-relevant problems in programmable and integrated photonics, optical amplifica...
Distributed Raman amplifier (DRA) has been widely studied in recent decades because of its low noise...
We propose an unsupervised machine learning method based on autoencoders to design the gain profile ...
We introduce a load aware machine learning method for prediction of Raman gain profiles. It enables ...
Two artificial neural network (ANN) models are presented to predict power profiles over C+L–band in ...
The paper presents recent advances in the design of controllable, highly accurate, and multi-band Ra...
We experimentally validate a real-time machine learning framework, capable of controlling the pump p...
We propose a Convolutional Neural Network (CNN) to learn the mapping between the 2D power profiles, ...
A machine learning technique was recently proposed to optimize the gain of a multi-pump single-mode...
Optical communication systems are always evolving to support the need for ever-increasing transmissi...
A multi-layer neural network is employed to learn the mapping between Raman gain profile and pump po...
It has been recently demonstrated that neural networks can learn the complex pump–signal relations i...
A machine learning framework for Raman amplifier design is experimentally tested. Performance in ter...
A machine learning framework predicting pump powers and noise figure profile for a target distribute...
One of the most promising solutions to overcome the capacity limit of current optical fiber links i...
A wide range of highly-relevant problems in programmable and integrated photonics, optical amplifica...
Distributed Raman amplifier (DRA) has been widely studied in recent decades because of its low noise...
We propose an unsupervised machine learning method based on autoencoders to design the gain profile ...
We introduce a load aware machine learning method for prediction of Raman gain profiles. It enables ...
Two artificial neural network (ANN) models are presented to predict power profiles over C+L–band in ...
The paper presents recent advances in the design of controllable, highly accurate, and multi-band Ra...