Adaptive Interface-PINNs (AdaI-PINNs) for inverse problems: Determining material properties for heterogeneous systems

Roy Sarkar, Dibakar; Annavarapu, Chandrasekhar; Roy, Pratanu

doi:10.1016/j.finel.2025.104373

Adaptive Interface-PINNs (AdaI-PINNs) for inverse problems: Determining material properties for heterogeneous systems

Journal Article · Thu May 29 00:00:00 EDT 2025 · Finite Elements in Analysis and Design

DOI:https://doi.org/10.1016/j.finel.2025.104373· OSTI ID:2571677

Roy Sarkar, Dibakar ^[1]; ^[1]; Roy, Pratanu ^[2]

Indian Institute of Technology Madras, Chennai (India)
Lawrence Livermore National Laboratory (LLNL), Livermore, CA (United States)

Here, we determine spatially varying discontinuous material properties using a domain-decomposition based physics-informed neural networks (PINNs) framework named the Adaptive Interface-PINNs or AdaI-PINNs (Roy et al., 2024). We propose the use of distinct neural networks for the field variables and material properties within each material, utilizing adaptive activation functions. While the neural networks across different materials share the same weights and biases, their activation functions are uniquely tailored using a hyperparameter that influences the slope of the activation function. The proposed framework is tested on several one-dimensional and two-dimensional benchmark examples, and its performance is compared with conventional PINNs and existing domain-decomposition PINNs frameworks, namely, the Multi-domain physics-informed neural network (M-PINN), and the eXtended physics-informed neural networks (XPINNs). The results demonstrate that the proposed approach can determine randomly distributed discontinuous material properties with an L₂ error of $$\mathscr{O}$$ (10^-3) for the material property and the root-mean-square error of $$\mathscr{O}$$ (10^-3) for the primary variable while the other approaches yield errors that are approximately two orders of magnitude larger (that is, $$\mathscr{O}$$ (10^-1)). Moreover, the spatial distribution of material properties obtained using the proposed framework is in close agreement with the true distribution, whereas the other approaches fare much worse. Additionally, the proposed approach is approximately 40% faster than its competitors, indicating its potential as a robust alternative for solving inverse problems in heterogeneous materials.

View Accepted Manuscript (DOE)

Research Organization:: Lawrence Livermore National Laboratory (LLNL), Livermore, CA (United States)

Sponsoring Organization:: ExxonMobil Corporation; USDOE National Nuclear Security Administration (NNSA)

Grant/Contract Number:: AC52-07NA27344

OSTI ID:: 2571677

Report Number(s):: LLNL--JRNL-868933

Journal Information:: Finite Elements in Analysis and Design, Journal Name: Finite Elements in Analysis and Design Vol. 249; ISSN 0168-874X

Publisher:: ElsevierCopyright Statement

Country of Publication:: United States

Language:: English

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