A Fiber Nonlinearity Compensation Scheme with Complex-Valued Dimension-Reduced Neural Network

Pinjing He; Feilong Wu; Meng Yang; Aiying Yang; Peng Guo; Yaojun Qiao; Xiangjun Xin

doi:10.1109/JPHOT.2021.3123624

A Fiber Nonlinearity Compensation Scheme with Complex-Valued Dimension-Reduced Neural Network

Pinjing He, Feilong Wu, Meng Yang^*, Aiying Yang, Peng Guo, Yaojun Qiao, Xiangjun Xin

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

10 Citations (Scopus)

Abstract

A fiber nonlinearity compensation scheme based on a complex-valued dimension-reduced neural network is proposed. The proposed scheme performs all calculations in complex values and employs a dimension-reduced triplet feature vector to reduce the size of the input layer. Simulation and experiment results show that the proposed neural network needed only 20% of computational complexity to reach the saturated performance gain of the real-valued triplet-input neural network, and had a similar saturated gain to the one-step-per-span digital backpropagation. In addition, the proposed scheme was 1.7 dB more robust to the noise from training data and required less bit precision for quantizing trained weights, compared with the real-valued triplet-input neural network.

Original language	English
Journal	IEEE Photonics Journal
Volume	13
Issue number	6
DOIs	https://doi.org/10.1109/JPHOT.2021.3123624
Publication status	Published - 1 Dec 2021

Keywords

Kerr effect
fiber nonlinearity compensation
neural network

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10.1109/JPHOT.2021.3123624

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abstract = "A fiber nonlinearity compensation scheme based on a complex-valued dimension-reduced neural network is proposed. The proposed scheme performs all calculations in complex values and employs a dimension-reduced triplet feature vector to reduce the size of the input layer. Simulation and experiment results show that the proposed neural network needed only 20% of computational complexity to reach the saturated performance gain of the real-valued triplet-input neural network, and had a similar saturated gain to the one-step-per-span digital backpropagation. In addition, the proposed scheme was 1.7 dB more robust to the noise from training data and required less bit precision for quantizing trained weights, compared with the real-valued triplet-input neural network.",

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AU - He, Pinjing

AU - Wu, Feilong

AU - Yang, Meng

AU - Yang, Aiying

AU - Guo, Peng

AU - Qiao, Yaojun

AU - Xin, Xiangjun

PY - 2021/12/1

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N2 - A fiber nonlinearity compensation scheme based on a complex-valued dimension-reduced neural network is proposed. The proposed scheme performs all calculations in complex values and employs a dimension-reduced triplet feature vector to reduce the size of the input layer. Simulation and experiment results show that the proposed neural network needed only 20% of computational complexity to reach the saturated performance gain of the real-valued triplet-input neural network, and had a similar saturated gain to the one-step-per-span digital backpropagation. In addition, the proposed scheme was 1.7 dB more robust to the noise from training data and required less bit precision for quantizing trained weights, compared with the real-valued triplet-input neural network.

AB - A fiber nonlinearity compensation scheme based on a complex-valued dimension-reduced neural network is proposed. The proposed scheme performs all calculations in complex values and employs a dimension-reduced triplet feature vector to reduce the size of the input layer. Simulation and experiment results show that the proposed neural network needed only 20% of computational complexity to reach the saturated performance gain of the real-valued triplet-input neural network, and had a similar saturated gain to the one-step-per-span digital backpropagation. In addition, the proposed scheme was 1.7 dB more robust to the noise from training data and required less bit precision for quantizing trained weights, compared with the real-valued triplet-input neural network.

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A Fiber Nonlinearity Compensation Scheme with Complex-Valued Dimension-Reduced Neural Network

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Keywords

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