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Computational Mechanics
Published in: Computational Mechanics 3/2023

13-01-2023 | Original Paper

Hybrid thermal modeling of additive manufacturing processes using physics-informed neural networks for temperature prediction and parameter identification

Authors: Shuheng Liao, Tianju Xue, Jihoon Jeong, Samantha Webster, Kornel Ehmann, Jian Cao

Published in: Computational Mechanics | Issue 3/2023

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Abstract

Understanding the thermal behavior of additive manufacturing (AM) processes is crucial for enhancing the quality control and enabling customized process design. Most purely physics-based computational models suffer from intensive computational costs and the need of calibrating unknown parameters, thus not suitable for online control and iterative design application. Data-driven models taking advantage of the latest developed computational tools can serve as a more efficient surrogate, but they are usually trained over a large amount of simulation data and often fail to effectively use small but high-quality experimental data. In this work, we developed a hybrid physics-based data-driven thermal modeling approach of AM processes using physics-informed neural networks. Specifically, partially observed temperature data measured from an infrared camera is combined with the physics laws to predict full-field temperature history and to discover unknown material and process parameters. In the numerical and experimental examples, the effectiveness of adding auxiliary training data and using the pretrained model on training efficiency and prediction accuracy, as well as the ability to identify unknown parameters with partially observed data, are demonstrated. The results show that the hybrid thermal model can effectively identify unknown parameters and capture the full-field temperature accurately, and thus it has the potential to be used in iterative process design and real-time process control of AM.
previous article An asynchronous parallel high-throughput model calibration framework for crystal plasticity finite element constitutive models
next article Physics-informed deep learning for three-dimensional transient heat transfer analysis of functionally graded materials

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Metadata
Title
Hybrid thermal modeling of additive manufacturing processes using physics-informed neural networks for temperature prediction and parameter identification
Authors
Shuheng Liao
Tianju Xue
Jihoon Jeong
Samantha Webster
Kornel Ehmann
Jian Cao
Publication date
13-01-2023
Publisher
Springer Berlin Heidelberg
Published in
Computational Mechanics / Issue 3/2023
Print ISSN: 0178-7675
Electronic ISSN: 1432-0924
DOI
https://doi.org/10.1007/s00466-022-02257-9

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