dc.contributor
Universitat Politècnica de Catalunya. Departament d'Enginyeria Mecànica
dc.contributor
Universitat Politècnica de Catalunya. ANiComp - Anàlisi Numèrica i Computació Científica
dc.contributor.author
Ortigosa, Rogelio
dc.contributor.author
Martínez Frutos, Jesús
dc.contributor.author
Pérez Escobar, Alberto
dc.contributor.author
Castañar Pérez, Inocencio
dc.contributor.author
Ellmer, Nathan
dc.contributor.author
Gil Ruiz, Antonio Javier
dc.date.issued
2025-03-15
dc.identifier
Ortigosa, R. [et al.]. A generalized theory for physics-augmented neural networks in finite strain thermo-electro-mechanics. «Computer methods in applied mechanics and engineering», 15 Març 2025, vol. 437, núm. article 117741.
dc.identifier
https://hdl.handle.net/2117/438808
dc.identifier
10.1016/j.cma.2025.117741
dc.description.abstract
This manuscript introduces a novel neural network-based computational framework for constitutive modeling of thermo-electro-mechanically coupled materials at finite strains, with four key innovations: (i) It supports calibration of neural network models with various input forms, such as ¿nn(F, E0, ¿), enn(F, D0, n), Ynn(F, E0, n), or Tnn(F, D0, o), with F representing the deformation gradient tensor, E0 and D0 the electric field and electric displacement field, respectively and finally, o and n, the temperature and entropy fields. These models comply with physical laws and material symmetries by utilizing isotropic or anisotropic invariants corresponding to the material’s symmetry group. (ii) A calibration approach is developed for the case of experimental data, where entropy n is typically unmeasurable. (iii) The framework accommodates models like e(F, D0, n), specially convenient for the imposition of polyconvexity across the three physics involved. A detailed calibration study is conducted evaluating various neural network architectures and considering a large variety of ground truth thermo-electromechanical constitutive models. The results demonstrate excellent predictive performance on larger datasets, validated through complex finite element simulations using both ground truth and neural network-based models. Crucially, the framework can be straightforwardly extended to scenarios involving other physics.
dc.description.abstract
R. Ortigosa, J. Martínez-Frutos and I. Castañar acknowledge the support of grant PID2022-141957OA-C22 funded by MI CIU/AEI/10.13039/501100011033 and by ‘‘ERDF A way of making Europe’’. R. Ortigosa and J. Martínez-Frutos also acknowledge
the support provided by the Autonomous Community of the Region of Murcia, Spain through the programme for the development of scientific and technical research by competitive groups (21996/PI/22), included in the Regional Program for the Promotion of
Scientific and Technical Research of Fundacion Seneca - Agencia de Ciencia 𝑦 Tecnologia de la Region de Murcia. N. Ellmer and A. J. Gil acknowledge the support provided by the defence, science and technology labora
dc.description.abstract
Peer Reviewed
dc.description.abstract
Postprint (published version)
dc.format
application/pdf
dc.relation
https://www.sciencedirect.com/science/article/pii/S0045782525000131?via%3Dihub
dc.rights
http://creativecommons.org/licenses/by/4.0/
dc.rights
Attribution 4.0 International
dc.subject
Àrees temàtiques de la UPC::Informàtica::Intel·ligència artificial::Aprenentatge automàtic
dc.subject
Neural networks
dc.subject
Machine learning
dc.subject
Thermo-electro-mechanics
dc.subject
Dielectric elastomers
dc.subject
Finite elements
dc.title
A generalized theory for physics-augmented neural networks in finite strain thermo-electro-mechanics
