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contributor authorOddiraju, Manaswin
contributor authorCleeman, Jeremy
contributor authorMalhotra, Rajiv
contributor authorChowdhury, Souma
date accessioned2025-04-21T10:03:11Z
date available2025-04-21T10:03:11Z
date copyright1/17/2025 12:00:00 AM
date issued2025
identifier issn1087-1357
identifier othermanu_147_5_051002.pdf
identifier urihttp://yetl.yabesh.ir/yetl1/handle/yetl/4305391
description abstractAdvanced manufacturing processes are often based on complex multiphysics phenomena that are either poorly understood or are computationally too expensive to simulate in the context of process design, control, or planning. Traditionally, simplified physics models with prescribed heuristics or purely data-driven surrogate models are used as alternatives in such applications. The concept of physics-informed machine learning (PIML) has been shown to have unique advantages over both of these alternatives in various fields of complex system analysis. In this paper, a new PIML approach is presented to model the geometry of the cut produced by a magnetically assisted laser-induced plasma micro-machining (M-LIPMM) process. This PIML architecture uses a neural network to auto-adapt the parametric boundary condition and physical properties used in a simplified finite difference-based physics model (of 2D heat conduction), as a function of the inputs namely the laser settings. This network also estimates the scaling and shifting parameters used by a convolutional neural network that takes the temperature profile predicted by the simplified heat conduction model to predict the width and depth of the machined cut. Trained on physical experiment data, the PIML approach compares favorably to a pure data-driven neural network model in extrapolation tests, while also providing physical insights (that the latter cannot). The PIML approach also provides an 85% better accuracy overall compared to the simplified physics model with heuristic settings.
publisherThe American Society of Mechanical Engineers (ASME)
titleA Differentiable Physics-Informed Machine Learning Approach to Model Laser-Based Micro-Manufacturing Process
typeJournal Paper
journal volume147
journal issue5
journal titleJournal of Manufacturing Science and Engineering
identifier doi10.1115/1.4067355
journal fristpage51002-1
journal lastpage51002-14
page14
treeJournal of Manufacturing Science and Engineering:;2025:;volume( 147 ):;issue: 005
contenttypeFulltext


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