Related papers: A Cutting Mechanics-based Machine Learning Modeling Method to Discover Governing Equations of Machining Dynamics

A Cutting Mechanics-based Machine Learning Modeling Method to Discover Governing Equations of Machining Dynamics

URL: http://arxiv.org/abs/2501.14817v1
Date: Mon, 20 Jan 2025 16:26:26 GMT
Title: A Cutting Mechanics-based Machine Learning Modeling Method to Discover Governing Equations of Machining Dynamics
Authors: Alisa Ren, Mason Ma, Jiajie Wu, Jaydeep Karandikar, Chris Tyler, Tony Shi, Tony Schmitz,
Abstract summary: This paper proposes a cutting mechanics-based machine learning (CMML) modeling method to discover governing equations of machining dynamics. Based on existing physics in cutting mechanics, CMML first establishes a general modeling structure governing machining dynamics. Numerical results show CMML can discover the exact milling dynamics models with process damping and edge force from noisy data.
Score: 1.5433033405381675
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Abstract: This paper proposes a cutting mechanics-based machine learning (CMML) modeling method to discover governing equations of machining dynamics. The main idea of CMML design is to integrate existing physics in cutting mechanics and unknown physics in data to achieve automated model discovery, with the potential to advance machining modeling. Based on existing physics in cutting mechanics, CMML first establishes a general modeling structure governing machining dynamics, that is represented by a set of unknown differential algebraic equations. CMML can therefore achieve data-driven discovery of these unknown equations through effective cutting mechanics-based nonlinear learning function space design and discrete optimization-based learning algorithm. Experimentally verified time domain simulation of milling is used to validate the proposed modeling method. Numerical results show CMML can discover the exact milling dynamics models with process damping and edge force from noisy data. This indicates that CMML has the potential to be used for advancing machining modeling in practice with the development of effective metrology systems.

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