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Constitutive Kolmogorov–Arnold Networks (CKANs): Combining accuracy and interpretability in data-driven material modeling

Kian P. Abdolazizi, Roland C. Aydin, Christian J. Cyron, Kevin Linka

2025Journal of the Mechanics and Physics of Solids18 citationsDOIOpen Access PDF

Abstract

Hybrid constitutive modeling integrates two complementary approaches for describing and predicting a material’s mechanical behavior: purely data-driven black-box methods and physically constrained, theory-based models. While black-box methods offer high accuracy, they often lack interpretability and extrapolability. Conversely, physics-based models provide theoretical insight and generalizability but may not capture complex behaviors with the same accuracy. Traditionally, hybrid modeling has required a trade-off between these aspects. In this paper, we show how recent advances in symbolic machine learning—specifically Kolmogorov–Arnold Networks (KANs)—help to overcome this limitation. We introduce Constitutive Kolmogorov–Arnold Networks (CKANs) as a new class of hybrid constitutive models. By incorporating a post-processing symbolification step, CKANs combine the predictive accuracy of data-driven models with the interpretability and extrapolation capabilities of symbolic expressions, bridging the gap between machine learning and physical modeling.

Topics & Concepts

InterpretabilityConstitutive equationArtificial intelligenceStatistical physicsAlgorithmComputer scienceMaterials scienceMathematicsApplied mathematicsPhysicsThermodynamicsFinite element methodElasticity and Material ModelingComposite Material MechanicsRheology and Fluid Dynamics Studies
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