Coevolution of machine learning and process-based modelling to revolutionize Earth and environmental sciences: A perspective

Saman Razavi; David M. Hannah; Amin Elshorbagy; Sujay Kumar; Lucy Marshall; Dimitri P. Solomatine; Amin Dezfuli; Mojtaba Sadegh; James Famiglietti

doi:10.1002/hyp.14596

Coevolution of machine learning and process-based modelling to revolutionize Earth and environmental sciences: A perspective

Saman Razavi^*, David M. Hannah, Amin Elshorbagy, Sujay Kumar, Lucy Marshall, Dimitri P. Solomatine, Amin Dezfuli, Mojtaba Sadegh, James Famiglietti

^*Corresponding author for this work

Water Resources

Research output: Contribution to journal › Comment/Letter to the editor › Scientific › peer-review

22 Citations (Scopus)

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Abstract

Machine learning (ML) applications in Earth and environmental sciences (EES) have gained incredible momentum in recent years. However, these ML applications have largely evolved in ‘isolation’ from the mechanistic, process-based modelling (PBM) paradigms, which have historically been the cornerstone of scientific discovery and policy support. In this perspective, we assert that the cultural barriers between the ML and PBM communities limit the potential of ML, and even its ‘hybridization’ with PBM, for EES applications. Fundamental, but often ignored, differences between ML and PBM are discussed as well as their strengths and weaknesses in light of three overarching modelling objectives in EES, (1) nowcasting and prediction, (2) scenario analysis, and (3) diagnostic learning. The paper ponders over a ‘coevolutionary’ approach to model building, shifting away from a borrowing to a co-creation culture, to develop a generation of models that leverage the unique strengths of ML such as scalability to big data and high-dimensional mapping, while remaining faithful to process-based knowledge base and principles of model explainability and interpretability, and therefore, falsifiability.

Original language	English
Article number	e14596
Number of pages	7
Journal	Hydrological Processes
Volume	36
Issue number	6
DOIs	https://doi.org/10.1002/hyp.14596
Publication status	Published - 2022

Keywords

artificial intelligence
deep learning
machine learning
modelling objective
policy support
predication
process-based modelling
scenarios
scientific discovery

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Hydrological Processes - 2022 - Razavi - Coevolution of machine learning and process‐based modelling to revolutionize EarthFinal published version, 1.17 MBLicence: CC BY-NC-ND

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title = "Coevolution of machine learning and process-based modelling to revolutionize Earth and environmental sciences: A perspective",

abstract = "Machine learning (ML) applications in Earth and environmental sciences (EES) have gained incredible momentum in recent years. However, these ML applications have largely evolved in {\textquoteleft}isolation{\textquoteright} from the mechanistic, process-based modelling (PBM) paradigms, which have historically been the cornerstone of scientific discovery and policy support. In this perspective, we assert that the cultural barriers between the ML and PBM communities limit the potential of ML, and even its {\textquoteleft}hybridization{\textquoteright} with PBM, for EES applications. Fundamental, but often ignored, differences between ML and PBM are discussed as well as their strengths and weaknesses in light of three overarching modelling objectives in EES, (1) nowcasting and prediction, (2) scenario analysis, and (3) diagnostic learning. The paper ponders over a {\textquoteleft}coevolutionary{\textquoteright} approach to model building, shifting away from a borrowing to a co-creation culture, to develop a generation of models that leverage the unique strengths of ML such as scalability to big data and high-dimensional mapping, while remaining faithful to process-based knowledge base and principles of model explainability and interpretability, and therefore, falsifiability.",

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author = "Saman Razavi and Hannah, {David M.} and Amin Elshorbagy and Sujay Kumar and Lucy Marshall and Solomatine, {Dimitri P.} and Amin Dezfuli and Mojtaba Sadegh and James Famiglietti",

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AU - Razavi, Saman

AU - Hannah, David M.

AU - Elshorbagy, Amin

AU - Kumar, Sujay

AU - Marshall, Lucy

AU - Solomatine, Dimitri P.

AU - Dezfuli, Amin

AU - Sadegh, Mojtaba

AU - Famiglietti, James

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Coevolution of machine learning and process-based modelling to revolutionize Earth and environmental sciences: A perspective

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