Smart finite elements: A novel machine learning application

Many multiscale finite element formulations can become computationally expensive because they rely on detailed models of the element’s internal displacement field. This issue is exacerbated in the presence of nonlinear problems, where numerical iterations are generally needed. We propose a method th...

Full description

Saved in:
Bibliographic Details
Published in:Computer methods in applied mechanics and engineering 2019-03, Vol.345, p.363-381
Main Authors: Capuano, German, Rimoli, Julian J.
Format: Article
Language:English
Subjects:
Algorithms
Angular momentum
Artificial intelligence
Error reduction
Finite element method
Finite elements
Formulations
Machine learning
Mathematical analysis
Mathematical models
Multiscale models
Nonlinear programming
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Many multiscale finite element formulations can become computationally expensive because they rely on detailed models of the element’s internal displacement field. This issue is exacerbated in the presence of nonlinear problems, where numerical iterations are generally needed. We propose a method that utilizes machine learning to generate a direct relationship between the element state and its forces, which avoids the complex task of finding the internal displacement field and eliminates the need for numerical iterations. To generate our model, we choose an existing finite element formulation, extract data from an instance of that element, and feed that data to the machine learning algorithm. The result is an approximated model of the element that can be used in the same context. Unlike most data-driven techniques applied to individual elements, our method is not tied to any particular machine learning algorithm, and it does not impose any restriction on the solver of choice. In addition, we guarantee that our elements are physically accurate by enforcing frame indifference and conservation of linear and angular momentum. Our results indicate that this can considerably reduce the error of the method and the computational cost of producing and solving the model. •We use machine learning to find the forces corresponding to the element’s state.•The method avoids the complex task of finding the internal displacement field.•We increase the performance of the method by enforcing known physical constraints.•The method is not tied to any particular machine learning algorithm.•The method does not impose any restriction on the solver of choice.
ISSN:0045-7825
1879-2138
DOI:10.1016/j.cma.2018.10.046