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Computation efficient sparse DNN nonlinear equalization for IM/DD 112  Gbps PAM4 inter-data center optical

Govind Sharan Yadav, Chun-Yen Chuang, Kai-Ming Feng

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    This study introduces a sparse deep neural network nonlinear equalizer (SDNN-NLE) that significantly cuts computational complexity. The novel approach effectively mitigates nonlinear distortions in high-speed optical communication systems.

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    Area of Science:

    • Optical communication systems engineering
    • Signal processing
    • Machine learning applications

    Background:

    • High-speed optical communication systems face nonlinear distortions.
    • Deep neural networks (DNNs) show promise for equalization but can be computationally intensive.
    • Existing methods like Volterra equalizers (VE) have limitations in complexity and performance.

    Purpose of the Study:

    • To propose and demonstrate a novel sparse deep neural network-based nonlinear equalizer (SDNN-NLE).
    • To reduce computational complexity while maintaining high transmission accuracy.
    • To mitigate nonlinear distortions in high-speed optical links.

    Main Methods:

    • Developed a two-phase pruning strategy for DNN weights: adaptive L2-regularization for significance identification and pre-defined sparsity for pruning.
    • Implemented and experimentally validated the SDNN-NLE on a 112 Gbps PAM4 optical link.
    • Compared performance against conventional fully connected Volterra equalizers and DNN-NLEs.

    Main Results:

    • The SDNN-NLE achieved significant complexity reductions: 71% vs. VE, 63% vs. fully connected DNN-NLE, and 41% vs. sparse VE.
    • Demonstrated effective mitigation of nonlinear distortions on a 112 Gbps PAM4 signal over 40 km standard single-mode fiber.
    • Maintained system performance without degradation compared to unpruned counterparts.

    Conclusions:

    • The proposed SDNN-NLE offers a computationally efficient and effective solution for mitigating nonlinear distortions in high-speed optical communication.
    • This sparse DNN approach presents a promising advancement over traditional equalization techniques.
    • The method successfully balances complexity reduction and transmission accuracy in demanding optical links.