Physics-Informed Mixture Models and Surrogate Models for Precision Additive Manufacturing

Sebastian Basterrech; Shuo Shan; Debabrata Adhikari; Sankhya Mohanty

Physics-Informed Mixture Models and Surrogate Models for Precision Additive Manufacturing

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Abstract

In this study, we leverage a mixture model learning approach to identify defects in laser-based Additive Manufacturing (AM) processes. By incorporating physics based principles, we also ensure that the model is sensitive to meaningful physical parameter variations. The empirical evaluation was conducted by analyzing real-world data from two AM processes: Directed Energy Deposition and Laser Powder Bed Fusion. In addition, we also studied the performance of the developed framework over public datasets with different alloy type and experimental parameter information. The results show the potential of physics-guided mixture models to examine the underlying physical behavior of an AM system.

Original language	English
Title of host publication	Proceedings of AI in Science Summit (AIS 2025)
Number of pages	5
Publication status	Submitted - 2026
Event	AI in Science Summit 2025 - Bella Center, Copenhagen, Denmark Duration: 3 Nov 2025 → 4 Nov 2025

Conference

Conference	AI in Science Summit 2025
Location	Bella Center
Country/Territory	Denmark
City	Copenhagen
Period	03/11/2025 → 04/11/2025

Keywords

Gaussian Mixture Models
Additive Manufacturing
Defect Detection
Laser Powder Bed Fusion
Physical Surrogate Models
Directed Energy Deposition

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@inproceedings{c5d3edcbe2ea4c70b9770033f8d42573,

title = "Physics-Informed Mixture Models and Surrogate Models for Precision Additive Manufacturing",

abstract = "In this study, we leverage a mixture model learning approach to identify defects in laser-based Additive Manufacturing (AM) processes. By incorporating physics based principles, we also ensure that the model is sensitive to meaningful physical parameter variations. The empirical evaluation was conducted by analyzing real-world data from two AM processes: Directed Energy Deposition and Laser Powder Bed Fusion. In addition, we also studied the performance of the developed framework over public datasets with different alloy type and experimental parameter information. The results show the potential of physics-guided mixture models to examine the underlying physical behavior of an AM system. ",

keywords = "Gaussian Mixture Models, Additive Manufacturing, Defect Detection, Laser Powder Bed Fusion, Physical Surrogate Models, Directed Energy Deposition",

author = "Sebastian Basterrech and Shuo Shan and Debabrata Adhikari and Sankhya Mohanty",

year = "2026",

language = "English",

booktitle = "Proceedings of AI in Science Summit (AIS 2025)",

note = "AI in Science Summit 2025, AIS25 ; Conference date: 03-11-2025 Through 04-11-2025",

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TY - GEN

T1 - Physics-Informed Mixture Models and Surrogate Models for Precision Additive Manufacturing

AU - Basterrech, Sebastian

AU - Shan, Shuo

AU - Adhikari, Debabrata

AU - Mohanty, Sankhya

PY - 2026

Y1 - 2026

N2 - In this study, we leverage a mixture model learning approach to identify defects in laser-based Additive Manufacturing (AM) processes. By incorporating physics based principles, we also ensure that the model is sensitive to meaningful physical parameter variations. The empirical evaluation was conducted by analyzing real-world data from two AM processes: Directed Energy Deposition and Laser Powder Bed Fusion. In addition, we also studied the performance of the developed framework over public datasets with different alloy type and experimental parameter information. The results show the potential of physics-guided mixture models to examine the underlying physical behavior of an AM system.

AB - In this study, we leverage a mixture model learning approach to identify defects in laser-based Additive Manufacturing (AM) processes. By incorporating physics based principles, we also ensure that the model is sensitive to meaningful physical parameter variations. The empirical evaluation was conducted by analyzing real-world data from two AM processes: Directed Energy Deposition and Laser Powder Bed Fusion. In addition, we also studied the performance of the developed framework over public datasets with different alloy type and experimental parameter information. The results show the potential of physics-guided mixture models to examine the underlying physical behavior of an AM system.

KW - Gaussian Mixture Models

KW - Additive Manufacturing

KW - Defect Detection

KW - Laser Powder Bed Fusion

KW - Physical Surrogate Models

KW - Directed Energy Deposition

M3 - Article in proceedings

BT - Proceedings of AI in Science Summit (AIS 2025)

T2 - AI in Science Summit 2025

Y2 - 3 November 2025 through 4 November 2025

ER -

Physics-Informed Mixture Models and Surrogate Models for Precision Additive Manufacturing

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