Please use this identifier to cite or link to this item:
https://hdl.handle.net/20.500.12008/41897
How to cite
Title: | Exploring the capability of pinns for solving material identification problems. |
Authors: | Díaz-Cuadro, C. Vanzulli, M. C. Galione, Pedro |
Type: | Ponencia |
Keywords: | PINNs, Material Identification |
Issue Date: | 2023 |
Abstract: | Physics-Informed Neural Networks (PINNs) have emerged as a promising approach for solving
scientific and engineering problems that involve partial differential equations or physical constraints.
PINNs are a type of neural network architecture that incorporates physical laws or governing equations
into its learning process. By combining the strengths of deep learning and physics-based modeling,
PINNs can learn complex patterns and relationships from data while simultaneously satisfying the governing
equations or physical laws. In this work, we explore the capabilities of PINNs to solve physical
problems and identify the material properties. The first validation example is 1D problem, in which the
heat generation number is estimated in a rectangular fin with temperature dependant thermal conductivity
and heat generation. The second example illustrates the behavior of a 2D linear-elastic beam subjected to
a uniform traction at its tip, experiencing negligible strains and plane stresses. The goal in this example
was to estimate the Young’s modulus. Finally, the third example studying here is a three-dimensional
solid with a Neo-Hookean material, loaded with a compressive traction at the opposite end. In this case,
the estimated parameters were the first and second Lame’s parameters. The reliability of the results was
assessed comparing against the analytical solution of each case. The ground truth displacement data
were obtained from analytical solution of the problem evaluated in selected data points. These values
were used as input to evaluate the loss data function, while the remaining loss functions were derived
from the physics of each problem. The results of this study suggest that PINNs have the potential to be an
effective tool for both material identification problems and real-time prediction of the physical solution. |
IN: | XXXIX Congreso Argentino de Mecánica Computacional - I Congreso Argentino Uruguayo de Mecánica Computacional. 6 -9 de noviembre de 2023. |
Citation: | Díaz-Cuadro, C., Vanzulli, M. y Galione, P. Exploring the capability of pinns for solving material identification problems [en línea] EN: XXXIX Congreso Argentino de Mecánica Computacional - I Congreso Argentino Uruguayo de Mecánica Computacional. 6 -9 de noviembre de 2023. 12 p. |
Appears in Collections: | Publicaciones académicas y científicas - Instituto de Ingeniería Mecánica y Producción Industrial |
This item is licensed under a Creative Commons License