Physics captured by data-based methods in El Niño prediction

G. Lancia; I. J. Goede; C. Spitoni; H. Dijkstra

doi:10.1063/5.0101668

Physics captured by data-based methods in El Niño prediction

G. Lancia^*, I. J. Goede, C. Spitoni, H. Dijkstra

^*Corresponding author for this work

Utrecht University

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

Abstract

On average once every four years, the Tropical Pacific warms considerably during events called El Niño, leading to weather disruptions over many regions on Earth. Recent machine-learning approaches to El Niño prediction, in particular, Convolutional Neural Networks (CNNs), have shown a surprisingly high skill at relatively long lead times. In an attempt to understand this high skill, we here use data from distorted physics simulations with the intermediate-complexity Zebiak-Cane model to determine what aspects of El Niño physics are represented in a specific CNN-based classification method. We find that the CNN can adequately correct for distortions in the ocean adjustment processes, but that the machine-learning method has far more trouble in dealing with distortions in upwelling feedback strength.

Original language	English
Article number	103115
Journal	Chaos
Volume	32
Issue number	10
DOIs	https://doi.org/10.1063/5.0101668
Publication status	Published - 1 Oct 2022

Bibliographical note

Funding Information:
The work by H.D. was sponsored by the Netherlands Science Foundation (NWO) through Project No. OCENW.M20.277.

Publisher Copyright:
© 2022 Author(s).

Funding

The work by H.D. was sponsored by the Netherlands Science Foundation (NWO) through Project No. OCENW.M20.277.

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title = "Physics captured by data-based methods in El Ni{\~n}o prediction",

abstract = "On average once every four years, the Tropical Pacific warms considerably during events called El Ni{\~n}o, leading to weather disruptions over many regions on Earth. Recent machine-learning approaches to El Ni{\~n}o prediction, in particular, Convolutional Neural Networks (CNNs), have shown a surprisingly high skill at relatively long lead times. In an attempt to understand this high skill, we here use data from distorted physics simulations with the intermediate-complexity Zebiak-Cane model to determine what aspects of El Ni{\~n}o physics are represented in a specific CNN-based classification method. We find that the CNN can adequately correct for distortions in the ocean adjustment processes, but that the machine-learning method has far more trouble in dealing with distortions in upwelling feedback strength.",

author = "G. Lancia and Goede, {I. J.} and C. Spitoni and H. Dijkstra",

note = "Funding Information: The work by H.D. was sponsored by the Netherlands Science Foundation (NWO) through Project No. OCENW.M20.277. Publisher Copyright: {\textcopyright} 2022 Author(s).",

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AU - Lancia, G.

AU - Goede, I. J.

AU - Spitoni, C.

AU - Dijkstra, H.

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N2 - On average once every four years, the Tropical Pacific warms considerably during events called El Niño, leading to weather disruptions over many regions on Earth. Recent machine-learning approaches to El Niño prediction, in particular, Convolutional Neural Networks (CNNs), have shown a surprisingly high skill at relatively long lead times. In an attempt to understand this high skill, we here use data from distorted physics simulations with the intermediate-complexity Zebiak-Cane model to determine what aspects of El Niño physics are represented in a specific CNN-based classification method. We find that the CNN can adequately correct for distortions in the ocean adjustment processes, but that the machine-learning method has far more trouble in dealing with distortions in upwelling feedback strength.

AB - On average once every four years, the Tropical Pacific warms considerably during events called El Niño, leading to weather disruptions over many regions on Earth. Recent machine-learning approaches to El Niño prediction, in particular, Convolutional Neural Networks (CNNs), have shown a surprisingly high skill at relatively long lead times. In an attempt to understand this high skill, we here use data from distorted physics simulations with the intermediate-complexity Zebiak-Cane model to determine what aspects of El Niño physics are represented in a specific CNN-based classification method. We find that the CNN can adequately correct for distortions in the ocean adjustment processes, but that the machine-learning method has far more trouble in dealing with distortions in upwelling feedback strength.

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Physics captured by data-based methods in El Niño prediction

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