Local and global optimization methods for optical line control based on quality of transmission

Giacomo Borraccini; Giacomo Borraccini; Stefano Straullu; Andrea D’Amico; Andrea D’Amico; Francesco Aquilino; Stefano Piciaccia; Alberto Tanzi; Gabriele Galimberti; Vittorio Curri

doi:10.1364/JOCN.512049

Journal of Optical Communications and Networking
Vol. 16,
Issue 5,
pp. B60-B70
(2024)
•https://doi.org/10.1364/JOCN.512049

Local and global optimization methods for optical line control based on quality of transmission

Giacomo Borraccini, Stefano Straullu, Andrea D’Amico, Francesco Aquilino, Stefano Piciaccia, Alberto Tanzi, Gabriele Galimberti, and Vittorio Curri

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Giacomo Borraccini, Stefano Straullu, Andrea D’Amico, Francesco Aquilino, Stefano Piciaccia, Alberto Tanzi, Gabriele Galimberti, and Vittorio Curri, "Local and global optimization methods for optical line control based on quality of transmission," J. Opt. Commun. Netw. 16, B60-B70 (2024)

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About this Article
History
- Original Manuscript: November 16, 2023
- Revised Manuscript: March 17, 2024
- Manuscript Accepted: March 18, 2024
- Published: April 8, 2024
Virtual Issues
Journal of Optical Communications and Networking Optical Network Design and Modeling (2024)

Abstract

The ever-increasing demand for data traffic in recent decades has pushed network operators to give importance to the aspect of infrastructure control to facilitate its scalability and maximize its capacity. A generic lightpath (LP) is deployed starting from a traffic request between a given pair of nodes in a network. LPs are operated in the network based on an estimate of the quality of transmission (QoT), which is derived from the physical layer characteristics of a selected route. Regardless of the model used to estimate QoT, it is necessary to calibrate the model to maximize its accuracy and define minimum design margins. The model calibration process depends significantly on the type of data that can be collected in the field (i.e., type of metric, resolution) and therefore on the available monitoring devices. In this work, a systematic evaluation of the QoT estimation is carried out on a multi-span erbium-doped-fiber-amplified optical line system (OLS) using in the first case only total power monitors and in the second experimentally emulating optical channel monitors (OCMs). Given the type of monitoring devices available, three different physical models are calibrated, and six optimization methods are used to define the optimal configuration of the target gain and tilt parameters of the optical amplifiers, jointly optimizing the working point of all amplifiers (global approach) or proceeding span by span (local approach). Subsequently, the OLS was set in each configuration obtained, and the generalized signal-to-noise ratio (GSNR) profile was measured at the end.

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SPAN ID #	$L_{S}$ [km]	$l_{t o t}$ [dB]	$α_{P D}$ [dB/km]	$\sum l (z)$ [dB]	$C_{R}$ [ $(W \cdot k m)^{- 1}$ ]	$A_{e f f}$ [ $µ m^{2}$ ]	$γ$ [ $(W \cdot k m)^{- 1}$ ]
1	106.179	23.2	0.208	5.7	0.42	75.9	1.39
2	107.510	22.9	0.201	1.7	0.40	75.1	1.40
3	106.179	22.5	0.202	2.5	0.40	83.0	1.27
4	108.825	22.3	0.195	4.1	0.42	79.2	1.33
5	108.278	23.0	0.201	4.0	0.42	85.0	1.24
6	106.195	23.9	0.215	3.6	0.32	79.0	1.33
7	106.791	23.8	0.210	6.0	0.40	76.3	1.38
8	106.424	21.1	0.188	7.6	0.32	78.1	1.35
9	107.273	23.6	0.209	2.3	0.42	79.4	1.33

Model	Method	Main Characteristics
PD	LOGO (1)	Analytical method requiring a low-complexity model
	GAIN SWEEP (2)	Empirical method that can be employed without using a model
PD $+$ INFO	GLOBAL GSNR (3), (4), NOISE (5), (6)	Stochastic method that requires a frequency-resolved model, exploring the entire problem space
OCM	LOCAL GSNR (7), (8), NOISE (9), (10)	Stochastic method based on a frequency-resolved model with a shorter execution time that remains limited as the number of spans increases

	EDFA ID	BST	ILA-1	ILA-2	ILA-3	ILA-4	ILA-5	ILA-6	ILA-7	ILA-8	PRE
MODEL-PD LOGO (1)	$P_{O U T}$ [dBm]	20.6	20.5	20.4	20.4	20.9	21.5	21.5	20.4	21.6	21.0
	$G$ [dB]	24.7	23.1	22.7	22.5	22.6	23.5	23.8	22.6	22.2	22.8
	$T$ [dB]	−2.3	−2.3	−2.3	−2.3	−2.3	−2.3	−2.3	−2.2	−2.2	0.0
MODEL-PD GAIN SWEEP (2)	$P_{O U T}$ [dBm]	16.3	16.3	16.3	16.5	16.8	16.8	17.1	17.1	17.2	17.4
	$G$ [dB]	20.3	23.3	22.8	22.6	22.4	23.0	24.0	23.6	21.2	23.6
	$T$ [dB]	−1.7	−1.7	−1.7	−1.7	−1.7	−1.7	−1.7	−1.6	−1.6	0.0
MODEL-PD + INFO GLOBAL GSNR (3)	$P_{O U T}$ [dBm]	19.4	18.5	17.9	17.4	17.4	17.3	16.8	15.4	16.1	19.2
	$G$ [dB]	23.4	22.4	22.2	22.0	22.2	22.9	23.3	22.3	21.8	26.5
	$T$ [dB]	−3.6	−0.6	−2.8	−1.2	−0.5	−2.1	−1.0	−0.4	−0.9	−2.0
MODEL-OCM GLOBAL GSNR (4)	$P_{O U T}$ [dBm]	19.0	19.0	19.3	19.7	19.9	19.9	20.8	19.6	20.3	22.9
	$G$ [dB]	23.0	23.2	23.1	22.9	22.4	23.0	24.8	22.6	21.8	26.1
	$T$ [dB]	−2.3	−1.5	−1.5	−1.8	−2.9	−4.3	0.0	−1.2	−3.6	−0.1
MODEL-PD + INFO LOCAL GSNR (5)	$P_{O U T}$ [dBm]	16.5	15.8	15.2	12.0	12.0	9.5	11.5	8.3	8.4	12.2
	$G$ [dB]	20.5	22.5	22.3	19.2	22.0	20.4	25.6	20.4	21.0	27.0
	$T$ [dB]	−1.1	−1.2	−1.2	−1.0	−1.0	−0.9	−1.0	−1.2	−0.9	−0.8
MODEL-OCM LOCAL GSNR (6)	$P_{O U T}$ [dBm]	15.3	16.5	15.9	15.9	16.6	14.5	12.1	10.8	12.5	16.2
	$G$ [dB]	19.3	24.4	22.3	22.4	22.9	20.8	21.4	22.3	22.7	27.0
	$T$ [dB]	−1.1	−1.8	−1.5	−1.6	−1.5	−1.3	−1.3	−1.7	−0.3	−0.8
MODEL-PD + INFO GLOBAL NOISE (7)	$P_{O U T}$ [dBm]	13.6	17.5	13.8	16.6	21.4	21.5	22.4	17.8	22.9	17.8
	$G$ [dB]	17.6	27.0	19.2	25.1	27.0	23.1	24.8	19.1	26.3	18.4
	$T$ [dB]	3.8	−4.2	1.1	−4.0	−5.0	−1.4	−2.5	−2.9	−1.1	−0.2
MODEL-OCM GLOBAL NOISE (8)	$P_{O U T}$ [dBm]	14.0	14.4	17.5	21.6	23.0	23.0	22.9	22.9	20.7	17.1
	$G$ [dB]	18.0	23.6	25.8	26.6	23.8	23.1	23.6	23.8	19.0	19.9
	$T$ [dB]	0.4	1.7	−4.9	−4.9	−4.7	−5.0	−3.4	−2.9	3.9	−3.5
MODEL-PD + INFO LOCAL NOISE (9)	$P_{O U T}$ [dBm]	20.8	19.2	19.0	17.8	18.0	17.3	17.6	15.7	15.5	19.0
	$G$ [dB]	24.8	21.7	22.6	21.3	22.4	22.3	24.1	21.8	20.9	27.0
	$T$ [dB]	−1.9	−1.8	−1.8	−1.7	−1.8	−1.7	−1.8	−1.4	−1.7	−0.8
MODEL-OCM LOCAL NOISE (10)	$P_{O U T}$ [dBm]	20.4	19.8	20.2	20.5	20.0	20.3	22.1	19.2	17.1	20.6
	$G$ [dB]	24.4	22.7	23.2	22.8	21.7	23.4	25.6	20.9	19.0	27.0
	$T$ [dB]	−2.0	−2.3	−2.1	−2.4	−2.2	−2.1	−2.4	−2.0	−0.5	−0.8

Optimization ID	$\bar{G S N R}$ [dB]	$σ_{G S N R}$ [dB]
(1)	14.2	0.49
(2)	11.6	0.46
(4)	13.9	0.46
(10)	13.8	0.58

SPAN ID #	$L_{S}$ [km]	$l_{t o t}$ [dB]	$α_{P D}$ [dB/km]	$\sum l (z)$ [dB]	$C_{R}$ [ $(W \cdot k m)^{- 1}$ ]	$A_{e f f}$ [ $µ m^{2}$ ]	$γ$ [ $(W \cdot k m)^{- 1}$ ]
1	106.179	23.2	0.208	5.7	0.42	75.9	1.39
2	107.510	22.9	0.201	1.7	0.40	75.1	1.40
3	106.179	22.5	0.202	2.5	0.40	83.0	1.27
4	108.825	22.3	0.195	4.1	0.42	79.2	1.33
5	108.278	23.0	0.201	4.0	0.42	85.0	1.24
6	106.195	23.9	0.215	3.6	0.32	79.0	1.33
7	106.791	23.8	0.210	6.0	0.40	76.3	1.38
8	106.424	21.1	0.188	7.6	0.32	78.1	1.35
9	107.273	23.6	0.209	2.3	0.42	79.4	1.33

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Journal of Optical Communications and Networking