Π-ML: a dimensional analysis-based machine learning parameterization of optical turbulence in the atmospheric surface layer

M. Pierzyna; R. Saathof; S. Basu

doi:10.1364/OL.492652

Π-ML: a dimensional analysis-based machine learning parameterization of optical turbulence in the atmospheric surface layer

M. Pierzyna, R. Saathof, S. Basu

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Abstract

Turbulent fluctuations of the atmospheric refraction index, so-called optical turbulence, can significantly distort propagating laser beams. Therefore, modeling the strength of these fluctuations (𝐶2𝑛) is highly relevant for the successful development and deployment of future free-space optical communication links. In this Letter, we propose a physics-informed machine learning (ML) methodology, Π-ML, based on dimensional analysis and gradient boosting to estimate 𝐶2𝑛. Through a systematic feature importance analysis, we identify the normalized variance of potential temperature as the dominating feature for predicting 𝐶2𝑛. For statistical robustness, we train an ensemble of models which yields high performance on the out-of-sample data of R2 = 0.958 ± 0.001.

Original language	English
Number of pages	4
Journal	Optics Letters
Volume	48
Issue number	17
DOIs	https://doi.org/10.1364/OL.492652
Publication status	Published - 2023

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title = "Π-ML: a dimensional analysis-based machine learning parameterization of optical turbulence in the atmospheric surface layer",

abstract = "Turbulent fluctuations of the atmospheric refraction index, so-called optical turbulence, can significantly distort propagating laser beams. Therefore, modeling the strength of these fluctuations (퐶2푛) is highly relevant for the successful development and deployment of future free-space optical communication links. In this Letter, we propose a physics-informed machine learning (ML) methodology, Π-ML, based on dimensional analysis and gradient boosting to estimate 퐶2푛. Through a systematic feature importance analysis, we identify the normalized variance of potential temperature as the dominating feature for predicting 퐶2푛. For statistical robustness, we train an ensemble of models which yields high performance on the out-of-sample data of R2 = 0.958 ± 0.001.",

author = "M. Pierzyna and R. Saathof and S. Basu",

year = "2023",

doi = "10.1364/OL.492652",

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volume = "48",

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T1 - Π-ML: a dimensional analysis-based machine learning parameterization of optical turbulence in the atmospheric surface layer

AU - Pierzyna, M.

AU - Saathof, R.

AU - Basu, S.

PY - 2023

Y1 - 2023

N2 - Turbulent fluctuations of the atmospheric refraction index, so-called optical turbulence, can significantly distort propagating laser beams. Therefore, modeling the strength of these fluctuations (퐶2푛) is highly relevant for the successful development and deployment of future free-space optical communication links. In this Letter, we propose a physics-informed machine learning (ML) methodology, Π-ML, based on dimensional analysis and gradient boosting to estimate 퐶2푛. Through a systematic feature importance analysis, we identify the normalized variance of potential temperature as the dominating feature for predicting 퐶2푛. For statistical robustness, we train an ensemble of models which yields high performance on the out-of-sample data of R2 = 0.958 ± 0.001.

AB - Turbulent fluctuations of the atmospheric refraction index, so-called optical turbulence, can significantly distort propagating laser beams. Therefore, modeling the strength of these fluctuations (퐶2푛) is highly relevant for the successful development and deployment of future free-space optical communication links. In this Letter, we propose a physics-informed machine learning (ML) methodology, Π-ML, based on dimensional analysis and gradient boosting to estimate 퐶2푛. Through a systematic feature importance analysis, we identify the normalized variance of potential temperature as the dominating feature for predicting 퐶2푛. For statistical robustness, we train an ensemble of models which yields high performance on the out-of-sample data of R2 = 0.958 ± 0.001.

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DO - 10.1364/OL.492652

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VL - 48

JO - Optics Letters

JF - Optics Letters

IS - 17

ER -

Π-ML: a dimensional analysis-based machine learning parameterization of optical turbulence in the atmospheric surface layer

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