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Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

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Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems. / Mansour, Mariane ; Faruk, Md Saifuddin; Laperle, Charles et al.
Yn: Journal of Lightwave Technology, 27.05.2024.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

HarvardHarvard

Mansour, M, Faruk, MS, Laperle, C, Reimer, M, O’Sullivan, M & Savory, SJ 2024, 'Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems', Journal of Lightwave Technology.

APA

Mansour, M., Faruk, M. S., Laperle, C., Reimer, M., O’Sullivan, M., & Savory, S. J. (2024). Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems. Journal of Lightwave Technology. Cyhoeddiad ar-lein ymlaen llaw.

CBE

Mansour M, Faruk MS, Laperle C, Reimer M, O’Sullivan M, Savory SJ. 2024. Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems. Journal of Lightwave Technology.

MLA

Mansour, Mariane et al. "Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems". Journal of Lightwave Technology. 2024.

VancouverVancouver

Mansour M, Faruk MS, Laperle C, Reimer M, O’Sullivan M, Savory SJ. Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems. Journal of Lightwave Technology. 2024 Mai 27. Epub 2024 Mai 27.

Author

Mansour, Mariane ; Faruk, Md Saifuddin ; Laperle, Charles et al. / Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems. Yn: Journal of Lightwave Technology. 2024.

RIS

TY - JOUR

T1 - Physics-Based Modeling for Hybrid Data-Driven Models to Estimate SNR in WDM Systems

AU - Mansour, Mariane

AU - Faruk, Md Saifuddin

AU - Laperle, Charles

AU - Reimer, Michael

AU - O’Sullivan, Maurice

AU - Savory, Seb J.

PY - 2024/5/27

Y1 - 2024/5/27

N2 - Recently several machine learning methods have been proposed to estimate the SNR, based on launch data and other system factors. These data-driven methods typically require a large number of datasets for training and generally are not interpretable. In this paper, we propose an alternative approach that requires less data and is interpretable, specifically a hybrid algorithm combining a physical model with Gaussian process regression. We develop a measurement-informed physical model, systematically reducing the number of independent parameters based on the underpinning physics and improve the overall performance of the physical model marginally. The model is validated using measurements performed on a 15-channel wavelength-division multiplexed system propagating over 1,000 km of standard single-mode fiber. The proposed hybrid model is not only interpretable but also obtains better agreement with measurements than a Gaussian process regression model and a simple neural network model for a given number of training datapoints.

AB - Recently several machine learning methods have been proposed to estimate the SNR, based on launch data and other system factors. These data-driven methods typically require a large number of datasets for training and generally are not interpretable. In this paper, we propose an alternative approach that requires less data and is interpretable, specifically a hybrid algorithm combining a physical model with Gaussian process regression. We develop a measurement-informed physical model, systematically reducing the number of independent parameters based on the underpinning physics and improve the overall performance of the physical model marginally. The model is validated using measurements performed on a 15-channel wavelength-division multiplexed system propagating over 1,000 km of standard single-mode fiber. The proposed hybrid model is not only interpretable but also obtains better agreement with measurements than a Gaussian process regression model and a simple neural network model for a given number of training datapoints.

M3 - Article

JO - Journal of Lightwave Technology

JF - Journal of Lightwave Technology

SN - 0733-8724

ER -