Abstract
Physics-informed machine learning is emerging through vast methodologies and in various applications. This paper discovers physics-based custom loss functions as an implementable solution to additive manufacturing (AM). Specifically, laser metal deposition (LMD) is an AM process where a laser beam melts deposited powder, and the dissolved particles fuse to produce metal components. Porosity, or small cavities that form in this printed structure, is generally considered one of the most destructive defects in metal AM. Traditionally, computer tomography scans measure porosity. While this is useful for understanding the nature of pore formation and its characteristics, purely physics-driven models lack real-time prediction ability. Meanwhile, a purely deep learning approach to porosity prediction leaves valuable physics knowledge behind. In this paper, a hybrid model that uses both empirical and simulated LMD data is created to show how various physics-informed loss functions impact the accuracy, precision, and recall of a baseline deep learning model for porosity prediction. In particular, some versions of the physics-informed model can improve the precision of the baseline deep learning-only model (albeit at the expense of overall accuracy).
Highlights
Different from previous the works [23,26], this paper focuses on the capability to combine simulated physical data with experimental data in the form of physics-informed custom loss functions built into deep learning models in the laser metal deposition (LMD) process
This work shows how incorporating both simulated and empirical physical LMD data into a deep learning model by means of altering the loss function impacts the accuracy, precision, and recall of said model as it attempts to predict porosity. While this physicsinformed model cannot improve the predictive capabilities of the deep learning model in every respect, some versions can improve the precision of the baseline model
This improvement in precision is due to an increase in the number of true positive predictions, but comes at the expense of the model’s overall accuracy
Summary
LMD has the advantages of a very high material build-up rate, 3D surface adaptability, and gradient layers. It can reduce the waste created during production, and it suits the production and repair of comprehensive and customized parts [2]. LMD printed a helicopter engine combustion chamber and achieved wall density of more than 99.5% throughout the part [3]. For these reasons, LMD is used in the production of high value-added parts in the aerospace, automotive, energy, petrochemical, and biomedical industries [4]
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