Nonlinear equalizer based on neural network in high-speed optical fiber communication systems

Han-qi ZHAO; Na LI; Bin WU; Gui-long WU; Yi-tong CHEN; Xiao-fang FENG; Pei-li HE; Wei LI

doi:10.37188/CO.2024-0114

Chinese Optics, Volume. 18, Issue 1, 114(2025)

Nonlinear equalizer based on neural network in high-speed optical fiber communication systems

Han-qi ZHAO¹, Na LI², Bin WU¹, Gui-long WU¹, Yi-tong CHEN¹, Xiao-fang FENG¹, Pei-li HE², and Wei LI^2、*

Author Affiliations

¹CSG Power Dispatching and Control Center, China Southern Power Grid Company, Ltd., Guangzhou 510663, China

²Wuhan National Laboratory for Optoelectronics, Huazhong University of Science and Technology, Wuhan 430074, China

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References(22)

[1] [1] CHAGNON M. Optical communications f sht reach[C]. Proceedings of 2018 European Conference on Optical Communication (ECOC), IEEE, 2018: 13.

[2] [2] LI D, DENG L, YE Y, et al. 4×96 Gbits PAM8 f shtreach applications employing lowcost DML without preequalization[C]. Proceedings of 2019 Optical Fiber Communications Conference Exhibition (OFC), IEEE, 2019: 13.

[3] [3] ZHANG F, FANG X S, CHEN X Y. Neural wkbased fiber nonlinearity mitigation in highspeed coherent optical transmission systems[C]. Proceedings of 2022 Optical Fiber Communications Conference Exhibition (OFC), IEEE, 2022: 13.

[4] [4] ALMUFTI A M, MOZOV O G. 1Tbits per lambda high der quadrature amplitude modulation (128256QAM) coherent optical transmission system design to suppt (5G+)[C]. Proceedings of 2023 Systems of Signal Synchronization, Generating Processing in Telecommunications (SYNCHROINFO), IEEE, 2023: 14.

[5] HARSTEAD E, VAN VEEN D, HOUTSMA V et al. Technology roadmap for time-division multiplexed passive optical networks (TDM PONs)[J]. Journal of Lightwave Technology, 37, 657-664(2019).

[6] WANG ZH Y, FU X H, LIN ZH W. Development of high-precision beam splitter for inter-satellite communication system[J]. Chinese Optics, 17, 334-341(2024).

[7] YANG X Q, CHEN H Y. Application of optical communication technique in the Internet of Things[J]. Chinese Optics, 7, 889-896(2014).

[8] ZHOU X, URATA R, LIU H. Beyond 1 Tb/s intra-data center interconnect technology: IM-DD OR coherent?[J]. Journal of Lightwave Technology, 38, 475-484(2020).

[9] [9] MANILOFF E, GAREAU S, MOYER M. 400 G beyond: coherent evolution to highcapacity inter data center links[C]. Proceedings of 2019 Optical Fiber Communications Conference Exhibition (OFC), IEEE, 2019: 13.

[10] [10] PANG X D, UDALCOVS A, SCHATZ R, et al. Highspeed sht reach optical communications: technological options challenges[C]. Proceedings of 2020 Asia Communications Photonics Conference (ACP) International Conference on Infmation Photonics Optical Communications (IPOC), IEEE, 2020: 13.

[11] ZHANG F, ZHU Y X. High-speed transmission technologies for data center optical interconnection[J]. ZTE Technology Journal, 25, 17-24(2019).

[12] ZHONG K P, ZHOU X, GAO Y L et al. 140-Gb/s 20-km transmission of PAM-4 signal at 1.3 μm for short reach communications[J]. IEEE Photonics Technology Letters, 27, 1757-1760(2015).

[13] YANG CH, HU R, LUO M et al. IM/DD-based 112-Gb/s/lambda PAM-4 transmission using 18-Gbps DML[J]. IEEE Photonics Journal, 8, 7903907(2016).

[14] [14] MATSUMOTO K, YOSHIDA Y, MARUTA A, et al. On the impact of TomlinsonHarashima precoding in optical PAM transmissions f intraDCN communication[C]. Proceedings of 2017 Optical Fiber Communications Conference Exhibition (OFC), IEEE, 2017: 13.

[15] GAO F, ZHOU SH W, LI X et al. 2 × 64 Gb/s PAM-4 transmission over 70 km SSMF using O-band 18G-class directly modulated lasers (DMLs)[J]. Optics Express, 25, 7230-7237(2017).

[16] [16] YU Y K, BO T W, CHE Y, et al. Lowcomplexity nonlinear equalizer based on absolute operation f Cb PAM signal generated by using directly modulated laser[C]. Proceedings of 2020 OptoElectronics Communications Conference (OECC), IEEE, 2020: 13.

[17] ZHANG J W, LIN ZH R, WU X et al. Low-complexity sparse absolute-term based nonlinear equalizer for C-band IM/DD systems[J]. Optics Express, 29, 21891-21901(2021).

[18] [18] CHEN Y B, WANG Y, LI W, et al. 106 Gbits PAM4 transmission employing a 15 GHz directly modulated laser[C]. Proceedings of 2021 Asia Communications Photonics Conference (ACP), IEEE, 2021: 13.

[19] [19] ESTARAN J, RIOSMUELLER R, MESTRE M A, et al. Artificial neural wks f linear nonlinear impairment mitigation in highbaudrate IMDD systems[C]. Proceedings of the ECOC 2016; 42nd European Conference on Optical Communication, IEEE, 2016: 13.

[20] [20] LI P X, YI L L, XUE L, et al. 56 Gbps IMDD PON based on 10Gclass optical devices with 29 dB loss budget enabled by machine learning[C]. Proceedings of 2018 Optical Fiber Communications Conference Exposition (OFC), IEEE, 2018: 13.

[21] [21] YE CH H, ZHANG D X, HU X F, et al. Recurrent Neural wk (RNN) based endtoend nonlinear management f symmetrical 50Gbps NRZ PON with 29dB+ loss budget[C]. Proceedings of 2018 European Conference on Optical Communication (ECOC), IEEE, 2018: 13.

[22] [22] XU ZH P, SUN CH B W, JI T H, et al. Cade recurrent neural wk enabled 100Gbs PAM4 shtreach optical link based on DML[C]. Proceedings of 2020 Optical Fiber Communications Conference Exhibition (OFC), IEEE, 2020: 13.

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Han-qi ZHAO, Na LI, Bin WU, Gui-long WU, Yi-tong CHEN, Xiao-fang FENG, Pei-li HE, Wei LI. Nonlinear equalizer based on neural network in high-speed optical fiber communication systems[J]. Chinese Optics, 2025, 18(1): 114

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Paper Information

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Received: Jun. 21, 2024

Accepted: Aug. 30, 2024

Published Online: Mar. 14, 2025

The Author Email:

DOI:10.37188/CO.2024-0114

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