Gradient information and regularization for gene expression programming to develop data-driven physics closure models
Gradient information and regularization for gene expression programming to develop data-driven physics closure models
Learning accurate numerical constants when developing algebraic models is a known challenge for evolutionary algorithms, such as Gene Expression Programming (GEP). This paper introduces the concept of adaptive symbols to the GEP framework by Weatheritt and Sandberg (2016) to develop advanced physics closure models. Adaptive symbols utilize gradient information to learn locally optimal numerical constants during model training, for which we investigate two types of nonlinear optimization algorithms. The second contribution of this work is implementing two regularization techniques to incentivize the development of implementable and interpretable closure models. We apply $L_2$ regularization to ensure small magnitude numerical constants and devise a novel complexity metric that supports the development of low complexity models via custom symbol complexities and multi-objective optimization. This extended framework is employed to four use cases, namely rediscovering Sutherland's viscosity law, developing laminar flame speed combustion models and training two types of fluid dynamics turbulence models. The model prediction accuracy and the convergence speed of training are improved significantly across all of the more and less complex use cases, respectively. The two regularization methods are essential for developing implementable closure models and we demonstrate that the developed turbulence models substantially improve simulations over state-of-the-art models.
physics.comp-ph
Waschkowski, Fabian
b98ddf08-f427-448a-9a24-84a80df4b29e
Li, Haochen
492769a5-b35b-4249-b1d5-bae78a912494
Deshmukh, Abhishek
f742182f-5891-4f28-a1f7-4d60de974e03
Grenga, Temistocle
be0eba30-74b5-4134-87e7-3a2d6dd3836f
Zhao, Yaomin
7178210e-47cc-4047-850a-756321017477
Pitsch, Heinz
3dc0eb6e-deca-4742-98a1-f0cdd62ff8b8
Klewicki, Joseph
ea1a0bdf-6118-4948-b705-68c33fa7d227
Sandberg, Richard D.
41d03f60-5d12-4f2d-a40a-8ff89ef01cfa
22 November 2022
Waschkowski, Fabian
b98ddf08-f427-448a-9a24-84a80df4b29e
Li, Haochen
492769a5-b35b-4249-b1d5-bae78a912494
Deshmukh, Abhishek
f742182f-5891-4f28-a1f7-4d60de974e03
Grenga, Temistocle
be0eba30-74b5-4134-87e7-3a2d6dd3836f
Zhao, Yaomin
7178210e-47cc-4047-850a-756321017477
Pitsch, Heinz
3dc0eb6e-deca-4742-98a1-f0cdd62ff8b8
Klewicki, Joseph
ea1a0bdf-6118-4948-b705-68c33fa7d227
Sandberg, Richard D.
41d03f60-5d12-4f2d-a40a-8ff89ef01cfa
[Unknown type: UNSPECIFIED]
Abstract
Learning accurate numerical constants when developing algebraic models is a known challenge for evolutionary algorithms, such as Gene Expression Programming (GEP). This paper introduces the concept of adaptive symbols to the GEP framework by Weatheritt and Sandberg (2016) to develop advanced physics closure models. Adaptive symbols utilize gradient information to learn locally optimal numerical constants during model training, for which we investigate two types of nonlinear optimization algorithms. The second contribution of this work is implementing two regularization techniques to incentivize the development of implementable and interpretable closure models. We apply $L_2$ regularization to ensure small magnitude numerical constants and devise a novel complexity metric that supports the development of low complexity models via custom symbol complexities and multi-objective optimization. This extended framework is employed to four use cases, namely rediscovering Sutherland's viscosity law, developing laminar flame speed combustion models and training two types of fluid dynamics turbulence models. The model prediction accuracy and the convergence speed of training are improved significantly across all of the more and less complex use cases, respectively. The two regularization methods are essential for developing implementable closure models and we demonstrate that the developed turbulence models substantially improve simulations over state-of-the-art models.
Text
2211.12341v1
- Author's Original
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Published date: 22 November 2022
Keywords:
physics.comp-ph
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Local EPrints ID: 478247
URI: http://eprints.soton.ac.uk/id/eprint/478247
PURE UUID: e2d36f34-da04-46c0-be77-ba0e7ab2b2e9
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Date deposited: 26 Jun 2023 16:47
Last modified: 17 Mar 2024 04:19
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Contributors
Author:
Fabian Waschkowski
Author:
Haochen Li
Author:
Abhishek Deshmukh
Author:
Temistocle Grenga
Author:
Yaomin Zhao
Author:
Heinz Pitsch
Author:
Joseph Klewicki
Author:
Richard D. Sandberg
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