Machine Learning Models for Estimating Quality of Transmission in DWDM Networks

Rui Manuel Morais; João Pedro

doi:10.1364/JOCN.10.000D84

Journal of Optical Communications and Networking
Vol. 10,
Issue 10,
pp. D84-D99
(2018)
•https://doi.org/10.1364/JOCN.10.000D84

Machine Learning Models for Estimating Quality of Transmission in DWDM Networks

Rui Manuel Morais and João Pedro

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Rui Manuel Morais and João Pedro, "Machine Learning Models for Estimating Quality of Transmission in DWDM Networks," J. Opt. Commun. Netw. 10, D84-D99 (2018)

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Abstract

It is estimated that 5G and the Internet of Things (IoT) will impact traffic, both in volume and dynamicity, at unprecedented rates. Thus, to cost-efficiently accommodate these challenging requirements, optical networks must become more responsive to changes impacting the traffic and network state as well as operate more closely to optimality. In this context, knowledge-defined networking (KDN) promises to play a paramount role in improving network flexibility and automation. KDN is a solution that introduces reasoning processes and machine learning techniques into the control plane of the network, enabling it to operate autonomously and faster. One of the key aspects in this environment is the accurate validation of lightpaths. Accurate lightpath validation demands running computationally intensive performance models, which can be time-consuming and impact time-critical applications (e.g., optical channel restoration). This work evaluates the effectiveness of various machine learning models when used to predict the quality of transmission (QoT) of an unestablished lightpath, speeding up the process of lightpath provisioning. Three network scenarios to efficiently generate the knowledge database used to train the models are proposed as well as an overview of the most-used machine learning models. The considered models are: K-nearest neighbors, logistic regression, support vector machines, and artificial neural networks. Results show that, in general, all machine learning models are able to correctly predict the QoT of more than 90% of the lightpaths. However, the artificial neural networks (ANN) model is the model presenting better generalization, being able to correctly predict the QoT of almost 99.9% of the lightpaths. Moreover, ANN is able to estimate the residual margin of a lightpath with an average error of only 0.4 dB.

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Rui Manuel Morais	https://orcid.org/0000-0002-4396-5916
João Pedro	https://orcid.org/0000-0003-4471-7401

Network	Nodes	Links	Av. Nodal Degree	Av. Link Length	Fiber Types	Number of Paths
GBN [24]	12	20	3.3	243.0	SSMF	4099
TIM [25]	44	71	3.2	174.3	SSMF	1134272
TIM [25]	44	71	3.2	174.3	LEAF	1134272
SPARKLE [25]	49	72	2.9	388.0	SSMF	241115
SPARKLE [25]	49	72	2.9	388.0	LEAF	241115
CORONET [24]	75	82	2.2	396.0	SSMF	105320

Bit Rate [GB/s]	Symbol Rate [Gbaud]	Modulation Format	${OSNR}_{B2B}$ [dB]
100	32	QPSK	11
150	32	8QAM	15
200	32	16QAM	18
250	32	32QAM	21
300	32	64QAM	24

Fiber Type	Attenuation Parameter [dB/km]	Dispersion Parameter [ps/nm/km]	Nonlinear Coefficient [1/W/km]
SSMF	0.21	17	1.3
LEAF	0.22	3.8	1.5

p		GBN	TIM	SPARKLE	CORONET
0.1%	Positive	—	2478	556	265
0.1%	Negative	—	2840	605	265
	Total	—	5318	1161	530
1%	Positive	105	18,697	3193	1904
1%	Negative	84	28,359	6030	2635
	Total	189	47,056	9223	4539
5%	Positive	437	72,789	9144	6478
5%	Negative	412	141,785	30,140	13,165
	Total	849	214,574	39,284	19,643
10%	Positive	745	129,503	15,172	10,243
10%	Negative	820	283,570	60,280	26,330
	Total	1565	413,073	75,452	36,573
50%	Positive	2848	498,104	27,232	31,307
50%	Negative	4008	1,206,895	301,395	131,650
	Total	6856	1,704,999	328,627	162,957
100%	Positive	8065	1,272,926	27,253	38,021
100%	Negative	12,430	4,398,434	1,178,322	488,579
	Total	20,495	5,671,360	1,205,575	526,600

		KNN					SVM					ANN
		Euc. $K = 1$	Euc. $K = 10$	Cos. $K = 10$	Wei. $K = 10$	Logistic Regression	Linear	Quadratic	Cubic	Gaus.—1	Gaus.—3	Class.	Regre.
GBN	Accuracy	96.47	92.93	90.49	95.44	95.95	93.13	95.87	96.62	91.79	93.05	97.63	99.44
	False Positive	2.68	4.75	6.44	3.10	2.84	4.09	2.52	1.97	7.17	4.62	1.63	0.45
	False Negative	0.85	2.32	3.07	1.45	1.21	2.77	1.62	1.41	1.04	2.33	0.74	0.10
TIM	Accuracy	97.45	96.76	96.05	97.00	99.08	98.17	98.89	99.01	98.04	97.64	98.24	99.71
	False Positive	1.61	1.85	2.20	1.91	0.54	1.21	0.70	0.65	1.28	1.45	1.02	0.16
	False Negative	0.94	1.39	1.76	1.09	0.37	0.62	0.41	0.33	0.69	0.91	0.74	0.13
SPK	Accuracy	97.40	97.47	97.21	97.26	98.40	97.82	97.93	98.29	96.96	97.56	98.32	99.49
	False Positive	2.54	2.49	2.73	2.72	1.59	2.18	2.06	1.69	3.03	2.44	1.66	0.34
	False Negative	0.07	0.04	0.07	0.02	0.01	0.00	0.01	0.02	0.01	0.00	0.02	0.16
COR	Accuracy	97.05	96.90	96.16	96.91	96.98	97.87	97.58	97.89	95.91	97.52	98.41	99.90
	False Positive	2.57	2.75	3.24	2.83	2.93	2.00	2.32	1.97	3.96	2.26	1.51	0.04
	False Negative	0.37	0.34	0.61	0.27	0.09	0.13	0.10	0.14	0.13	0.22	0.08	0.06

	Features	GBN	TIM	SPK	COR
Average [dB]	All	0.104	0.078	0.337	0.046
Average [dB]	Ref. [11]	0.136	0.304	0.660	0.475
Std. Dev. [dB]	All	0.189	0.231	0.296	0.057
Std. Dev. [dB]	Ref. [11]	0.193	0.269	0.600	0.409
Max. [dB]	All	3.310	6.727	7.004	1.879
Max. [dB]	Ref. [11]	1.288	4.222	45.558	4.091
Min [dB]	All	−5.413	−15.502	−10.808	−7.254
Min [dB]	Ref. [11]	−6.968	−8.050	−8.790	−9.174

Machine Learning Models for Estimating Quality of Transmission in DWDM Networks

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Tables (6)

Equations (23)

Journal of Optical Communications and Networking