Experimental investigation of machine-learning-based soft-failure management using the optical spectrum

Lars E. Kruse; Sebastian Kühl; Annika Dochhan; Stephan Pachnicke

doi:10.1364/JOCN.500930

Journal of Optical Communications and Networking
Vol. 16,
Issue 2,
pp. 94-103
(2024)
•https://doi.org/10.1364/JOCN.500930

Experimental investigation of machine-learning-based soft-failure management using the optical spectrum

Lars E. Kruse, Sebastian Kühl, Annika Dochhan, and Stephan Pachnicke

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Lars E. Kruse, Sebastian Kühl, Annika Dochhan, and Stephan Pachnicke, "Experimental investigation of machine-learning-based soft-failure management using the optical spectrum," J. Opt. Commun. Netw. 16, 94-103 (2024)

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Abstract

The demand for high-speed data is exponentially growing. To conquer this, optical networks have undergone significant changes, getting more complex and versatile. The increasing complexity necessitates that the fault management be more adaptive to enhance network assurance. In this paper, we experimentally compare the performance of soft-failure management of different machine learning algorithms. We further introduce a machine-learning-based soft-failure management framework. It utilizes a variational autoencoder-based generative adversarial network (VAE-GAN) running on optical spectral data obtained by optical spectrum analyzers. The framework is able to reliably run on a fraction of available training data as well as identify unknown failure types. The investigations show that the VAE-GAN outperforms the other machine learning algorithms when up to 10% of the total training data are available in identification tasks. Furthermore, the advanced training mechanism for the GAN shows a high F1-score for unknown spectrum identification. The failure localization comparison shows the advantage of a low complexity neural network in combination with a VAE over established machine learning algorithms.

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Literature	SFD	SFI	SFL	OPM Data	ML-Algorithm	SFD Acc.	SFI Acc.	SFL Acc.
Vela et al. [3]	$\sqrt$	$\sqrt$		Rx power, BER	Analytical model	99.06%	99.55%
Furdek et al. [4]	$\sqrt$			BER, block errors, etc.	DBSCAN, SVM	96.2%
Shariati et al. [5]	$\sqrt$	$\sqrt$		Optical spectrum (1 Ch.)	SVM	Up to 100%	Up to 100%
Lun et al. [6]		$\sqrt$		PSD	CNN		Up to 100%
Mayer et al. [7]			$\sqrt$	Tx power, OSNR	ANN			Up to 100%
Abdelli et al. [8]	$\sqrt$		$\sqrt$	OTDR	LSTM	$92 \pm 1.06 %$		$2.2 \pm 0.13$ m
This paper	$\sqrt$	$\sqrt$	$\sqrt$	Optical spectrum	VAE-GAN	99.72%	98.21%	99.82%

Soft Failure	Range	Steps
EDFA noise figure increase	0.2–2 dB	0.2 dB
Transmit laser drift	−2.5 to 2.5 GHz	0.5 GHz
Transmit laser power drop	−2.5 to 2.5 dBm	0.5 dBm
Filter tightening	1 to 5 GHz	1 GHz
Filter shift	−2 to 2 GHz	1 GHz

Parameter	Value
Modulation format	DP-QPSK,
	DP-8-QAM,
	DP-16-QAM
Symbol rate	32 Gbaud
Channel spacing	37.5 GHz
Number of channels	1, 3, 5
Launch power	−3, −2, −1, 0 dBm
Center wavelength	1550.004 nm
Loop length	265.2 km
Loop iterations	1–6
OSA resolution	10 pm
OSA points	501

Framework Stage	Max. F1-Score
Soft-failure detection	0.9941
Soft-failure identification	0.9821
Unknown spectrum identification	0.9912

	Identification	Localization
ML Algorithm	Max. F1-Score	Max. F1-Score
Linear CLF	0.8913	0.9872
KNN	0.9925	0.9924
SVC	0.9943	0.9939
CLT	0.9642	0.9723
RFC	0.9684	0.9945
VAE-NN	0.9973	0.9982
VAE-GAN	0.9821	/

ML Algorithm	Training Time in s	Prediction Time in s
Linear CLF	0.6493	0.0035
KNN	0.1562	0.0040
SVC	0.6760	0.3854
CLT	0.6452	0.0045
RFC	0.7884	0.0080
VAE-NN	34.3143	0.0872
VAE-GAN	1074.3471	0.1285

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Journal of Optical Communications and Networking