Abstract
Multichannel digital equalization has proved capable of mitigating fiber-induced
inter-channel impairments which constitute a main limitation in wavelength-division multiplexed systems. In this paper, we present three multiple-input-multiple-output learned equalization architectures based on the inverse Volterra series transfer function (IVSTF): a fully parallel frequency-domain approach (L-IVSTF), a field-enhanced version with improved adaptability (FE L-IVSTF), and a time-domain implementation (L-simIVSTF). We demonstrate that machine-learning optimization enables efficient multichannel equalization for all the structures, with the 9 × 9 L-simIVSTF and FE L-IVSTF equalizers achieving an average signal-to-noise ratio improvement of ∼2.2 dB over chromatic dispersion compensation. The three models are thoroughly characterized and compared in terms of performance and computational cost, pinpointing the FE L-IVSTF as the model with the best trade-off.
inter-channel impairments which constitute a main limitation in wavelength-division multiplexed systems. In this paper, we present three multiple-input-multiple-output learned equalization architectures based on the inverse Volterra series transfer function (IVSTF): a fully parallel frequency-domain approach (L-IVSTF), a field-enhanced version with improved adaptability (FE L-IVSTF), and a time-domain implementation (L-simIVSTF). We demonstrate that machine-learning optimization enables efficient multichannel equalization for all the structures, with the 9 × 9 L-simIVSTF and FE L-IVSTF equalizers achieving an average signal-to-noise ratio improvement of ∼2.2 dB over chromatic dispersion compensation. The three models are thoroughly characterized and compared in terms of performance and computational cost, pinpointing the FE L-IVSTF as the model with the best trade-off.
| Original language | English |
|---|---|
| Article number | 16717 |
| Number of pages | 21 |
| Journal | Optics Express |
| Volume | 38 |
| Issue number | 8 |
| DOIs | |
| Publication status | Published - 7 Apr 2025 |
Bibliographical note
Copyright © Journal, 2025. Published by Optica Publishing Group under the terms of the Creative Commons Attribution 4.0 License. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.Funding
Engineering and Physical Sciences Research Council (EP/R035342/1, EP/X019241/1); North Atlantic Treaty Organization (G6137).
| Funders | Funder number |
|---|---|
| Engineering and Physical Sciences Research Council | EP/R035342/1, EP/X019241/1 |
| North Atlantic Treaty Organization | G6137 |
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