Evolutionary neuron-level transfer learning for QoT estimation in optical networks

Yuhang Zhou; Zhiqun Gu; Jiawei Zhang; Yuefeng Ji

doi:10.1364/JOCN.514618

Journal of Optical Communications and Networking
Vol. 16,
Issue 4,
pp. 432-448
(2024)
•https://doi.org/10.1364/JOCN.514618

Evolutionary neuron-level transfer learning for QoT estimation in optical networks

Yuhang Zhou, Zhiqun Gu, Jiawei Zhang, and Yuefeng Ji

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Yuhang Zhou, Zhiqun Gu, Jiawei Zhang, and Yuefeng Ji, "Evolutionary neuron-level transfer learning for QoT estimation in optical networks," J. Opt. Commun. Netw. 16, 432-448 (2024)

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Abstract

To ensure the reliability and efficiency of lightpath transmission in optical networks, it is essential to predict the quality of transmission (QoT) of the candidate lightpaths before their deployment. An artificial neural network (ANN) becomes a promising solution for QoT estimation of lightpaths, owing to its powerful data fitting capability and scalability. As a supervised learning model, an ANN requires a large set of training samples from lightpaths’ observations to ensure its accuracy. Unfortunately, the acquisition of the training samples is hindered by practical limitations, such as the shortage of monitorable lightpaths in the early stage of optical network deployment or/and the absence of optical performance monitors at partial network nodes. Therefore, how to obtain a high-precision QoT estimator with small-sized datasets is challenging. In this paper, we propose an evolutionary neuron-level transfer learning (ENTL) scheme for QoT estimation to improve the accuracy of the ANN model with small-sized datasets. In the ENTL-based QoT estimator, the minimal unit of knowledge transfer is the neuron of the ANN model, and the particle swarm optimization (PSO) algorithm is introduced to determine the trainable neurons and the frozen neurons, where the testing dataset generated by data augmentation assists the PSO algorithm to evaluate the feasible solutions. Simulation results show that the ENTL-based QoT estimator achieves higher accuracy than the traditional layer-level transfer learning (LTL)-based QoT estimator. And, when the ENTL-based QoT estimator is applied to optical network planning, it improves the reliability and throughput of optical networks compared with the LTL-based QoT estimator.

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QoT Estimation Schemes	Computational Complexity
ENTL-based QoT estimator	$n \times (I_{t h} + 1) + 1$
LTL-based QoT estimator	$A_{L + 1}^{L + 1}$

Schemes	OT ( $\| T_{t r a i n} = 50 \|$ )	OT ( $\| T_{t r a i n} = 100 \|$ )	OT ( $\| T_{t r a i n} = 200 \|$ )	OT ( $\| T_{t r a i n} = 300 \|$ )	OT ( $\| T_{t r a i n} = 500 \|$ )	OT ( $\| T_{t r a i n} = 700 \|$ )	OT ( $\| T_{t r a i n} = 1000 \|$ )
ENTL	176.38/6.17 /0.0024 ( $s$ )	154.11/5.92 /0.0024 ( $s$ )	311.42/9.24 /0.0022 ( $s$ )	571.27/15.74 /0.0022 ( $s$ )	782.37/18.86 /0.0021 ( $s$ )	980.37/26.96 /0.0021 ( $s$ )	1144.10/35.6 1/0.0021 ( $s$ )
LTL	24.53/3.60 /0.0028 ( $s$ )	25.40/3.50 /0.0036 ( $s$ )	50.05/8.90 /0.0026 ( $s$ )	64.10/11.24 /0.0024 ( $s$ )	84.60/15.46 /0.0025 ( $s$ )	134.17/19.56 /0.0023 ( $s$ )	174.92/33.69 /0.0024 ( $s$ )

Format	Min SNR (dB)	Data Rate (Gb/s)
PM-BPSK	3.7	50
PM-QPSK	6.7	100
PM-8QAM	10.8	150
PM-16QAM	13.2	200
PM-32QAM	16.2	250
PM-64QAM	19.0	300
PM-128QAM	21.8	350
PM-256QAM	24.7	400
PM-512QAM	27.4	450

QoT Estimation Schemes	Computational Complexity
ENTL-based QoT estimator	$n \times (I_{t h} + 1) + 1$
LTL-based QoT estimator	$A_{L + 1}^{L + 1}$

Schemes	OT ( $\| T_{t r a i n} = 50 \|$ )	OT ( $\| T_{t r a i n} = 100 \|$ )	OT ( $\| T_{t r a i n} = 200 \|$ )	OT ( $\| T_{t r a i n} = 300 \|$ )	OT ( $\| T_{t r a i n} = 500 \|$ )	OT ( $\| T_{t r a i n} = 700 \|$ )	OT ( $\| T_{t r a i n} = 1000 \|$ )
ENTL	176.38/6.17 /0.0024 ( $s$ )	154.11/5.92 /0.0024 ( $s$ )	311.42/9.24 /0.0022 ( $s$ )	571.27/15.74 /0.0022 ( $s$ )	782.37/18.86 /0.0021 ( $s$ )	980.37/26.96 /0.0021 ( $s$ )	1144.10/35.6 1/0.0021 ( $s$ )
LTL	24.53/3.60 /0.0028 ( $s$ )	25.40/3.50 /0.0036 ( $s$ )	50.05/8.90 /0.0026 ( $s$ )	64.10/11.24 /0.0024 ( $s$ )	84.60/15.46 /0.0025 ( $s$ )	134.17/19.56 /0.0023 ( $s$ )	174.92/33.69 /0.0024 ( $s$ )

Abstract

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Journal of Optical Communications and Networking