Dynamic mitigation of EDFA power excursions with machine learning

Yishen Huang; Craig L. Gutterman; Payman Samadi; Patricia B. Cho; Wiem Samoud; Cédric Ware; Mounia Lourdiane; Gil Zussman; Keren Bergman

doi:10.1364/OE.25.002245

Dynamic mitigation of EDFA power excursions with machine learning

Yishen Huang
, Craig L. Gutterman
, Payman Samadi
, Patricia B. Cho
, Wiem Samoud
, Cédric Ware
, Mounia Lourdiane
, Gil Zussman
, Keren Bergman

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

Abstract

Dynamic optical networking has promising potential to support the rapidly changing traffic demands in metro and long-haul networks. However, the improvement in dynamicity is hindered by wavelength-dependent power excursions in gain-controlled erbium doped fiber amplifiers (EDFA) when channels change rapidly. We introduce a general approach that leverages machine learning (ML) to characterize and mitigate the power excursions of EDFA systems with different equipment and scales. An ML engine is developed and experimentally validated to show accurate predictions of the power dynamics in cascaded EDFAs. Recommended channel provisioning based on the ML predictions achieves within 1% error of the lowest possible power excursion over 94% of the time. We also showcase significant mitigation of EDFA power excursions in super-channel provisioning when compared to the first-fit wavelength assignment algorithm.

Original language	English
Pages (from-to)	2245-2258
Number of pages	14
Journal	Optics Express
Volume	25
Issue number	3
DOIs	https://doi.org/10.1364/OE.25.002245
Publication status	Published - 6 Feb 2017
Externally published	Yes

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10.1364/OE.25.002245

Cite this

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title = "Dynamic mitigation of EDFA power excursions with machine learning",

abstract = "Dynamic optical networking has promising potential to support the rapidly changing traffic demands in metro and long-haul networks. However, the improvement in dynamicity is hindered by wavelength-dependent power excursions in gain-controlled erbium doped fiber amplifiers (EDFA) when channels change rapidly. We introduce a general approach that leverages machine learning (ML) to characterize and mitigate the power excursions of EDFA systems with different equipment and scales. An ML engine is developed and experimentally validated to show accurate predictions of the power dynamics in cascaded EDFAs. Recommended channel provisioning based on the ML predictions achieves within 1\% error of the lowest possible power excursion over 94\% of the time. We also showcase significant mitigation of EDFA power excursions in super-channel provisioning when compared to the first-fit wavelength assignment algorithm.",

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AU - Huang, Yishen

AU - Gutterman, Craig L.

AU - Samadi, Payman

AU - Cho, Patricia B.

AU - Samoud, Wiem

AU - Ware, Cédric

AU - Lourdiane, Mounia

AU - Zussman, Gil

AU - Bergman, Keren

PY - 2017/2/6

Y1 - 2017/2/6

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AB - Dynamic optical networking has promising potential to support the rapidly changing traffic demands in metro and long-haul networks. However, the improvement in dynamicity is hindered by wavelength-dependent power excursions in gain-controlled erbium doped fiber amplifiers (EDFA) when channels change rapidly. We introduce a general approach that leverages machine learning (ML) to characterize and mitigate the power excursions of EDFA systems with different equipment and scales. An ML engine is developed and experimentally validated to show accurate predictions of the power dynamics in cascaded EDFAs. Recommended channel provisioning based on the ML predictions achieves within 1% error of the lowest possible power excursion over 94% of the time. We also showcase significant mitigation of EDFA power excursions in super-channel provisioning when compared to the first-fit wavelength assignment algorithm.

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ER -

Dynamic mitigation of EDFA power excursions with machine learning

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