Physics-constrained symbolic regression for discovering closed-form equations of multimodal water retention curves from experimental data

• URL: http://arxiv.org/abs/2603.03346v1
• Date: Tue, 24 Feb 2026 18:48:15 GMT
• Title: Physics-constrained symbolic regression for discovering closed-form equations of multimodal water retention curves from experimental data
• Authors: Yejin Kim, Hyoung Suk Suh,
• Abstract summary: We introduce a physics-constrained machine learning framework designed for meta-modeling, enabling the automatic discovery of closed-form mathematical expressions for multimodal water retention curves directly from experimental data.<n>Our results demonstrate that the proposed framework can discover closed-form equations that effectively represent the water retention characteristics of porous materials with varying pore structures.
• Score: 1.1278037007482673
• License: http://creativecommons.org/licenses/by-nc-nd/4.0/
• Abstract: Modeling the unsaturated behavior of porous materials with multimodal pore size distributions presents significant challenges, as standard hydraulic models often fail to capture their complex, multi-scale characteristics. A common workaround involves superposing unimodal retention functions, each tailored to a specific pore size range; however, this approach requires separate parameter identification for each mode, which limits interpretability and generalizability, especially in data-sparse scenarios. In this work, we introduce a fundamentally different approach: a physics-constrained machine learning framework designed for meta-modeling, enabling the automatic discovery of closed-form mathematical expressions for multimodal water retention curves directly from experimental data. Mathematical expressions are represented as binary trees and evolved via genetic programming, while physical constraints are embedded into the loss function to guide the symbolic regressor toward solutions that are physically consistent and mathematically robust. Our results demonstrate that the proposed framework can discover closed-form equations that effectively represent the water retention characteristics of porous materials with varying pore structures. To support third-party validation, application, and extension, we make the full implementation publicly available in an open-source repository.

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