Evaluating a neural network and a convolutional neural network for predicting soliton properties in a quantum noise environment

Rodrigo Acuna Herrera

doi:10.1364/JOSAB.401936

Journal of the Optical Society of America B
Vol. 37,
Issue 10,
pp. 3094-3098
(2020)
•https://doi.org/10.1364/JOSAB.401936

Evaluating a neural network and a convolutional neural network for predicting soliton properties in a quantum noise environment

Rodrigo Acuna Herrera

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Rodrigo Acuna Herrera, "Evaluating a neural network and a convolutional neural network for predicting soliton properties in a quantum noise environment," J. Opt. Soc. Am. B 37, 3094-3098 (2020)

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Abstract

With its applications in science and engineering, supercontinuum (SC) generation is a phenomenon widely studied in nonlinear fiber optics. The SC spectral properties are not difficult to measure, except those related to time. Fortunately, machine learning can help predict the time behavior of various nonlinear optics phenomena using spectral characteristics. In this study, supervised machine learning tools are used to evaluate the prediction accuracy of the soliton properties in a noisy environment. A neural network (NN) and a convolutional neural network (CNN) are implemented to assess the performance of these techniques in relation to predicting soliton properties when noise is included in a laser that pumps a nonlinear fiber optics. We conclude that the CNN shows better performance compared with NN, as it involves more data with the same quantity of simulations conducted in both cases, whereas NN can better predict the target in the absence of noise.

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Parameter to Predict	NN-R	CNN-R	NN-RMSE	CNN-RMSE
$P_{s}$	0.98737	0.94829	0.01	0.0412
$T_{o, s}$	0.98308	0.57441	$4.3859 \times 10^{- 4}$	0.0102

$T_{F W H M} (f s)$	NN Prediction	CNN Prediction	NN-RMSE	CNN-RMSE
30	0.3754	0.3955	0.0947	$6.7103 \times 10^{- 4}$
50	0.3746	0.4199	0.0802	0.0021
80	0.4491	0.4067	0.064	0.0099
100	0.4805	0.4138	0.183	0.0190
150	0.5297	0.4526	0.198	0.0523

Parameter to Predict	NN-R	CNN-R	NN-RMSE	CNN-RMSE
$P_{s}$	0.98737	0.94829	0.01	0.0412
$T_{o, s}$	0.98308	0.57441	$4.3859 \times 10^{- 4}$	0.0102

$T_{F W H M} (f s)$	NN Prediction	CNN Prediction	NN-RMSE	CNN-RMSE
30	0.3754	0.3955	0.0947	$6.7103 \times 10^{- 4}$
50	0.3746	0.4199	0.0802	0.0021
80	0.4491	0.4067	0.064	0.0099
100	0.4805	0.4138	0.183	0.0190
150	0.5297	0.4526	0.198	0.0523

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Journal of the Optical Society of America B