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A Gaussian process regression‐based surrogate model of the varying workpiece dynamics for chatter prediction in milling of thin‐walled structures

Yun Yang, Yun Yang, Yang Yang, Yang Yang, Manyu Xiao, Min Wan, Weihong Zhang

2022International journal of mechanical system dynamics20 citationsDOIOpen Access PDF

Abstract

Abstract Since the dynamics of thin‐walled structures instantaneously varies during the milling process, accurate and efficient prediction of the in‐process workpiece (IPW) dynamics is critical for the prediction of chatter stability of milling of thin‐walled structures. This article presents a surrogate model of the IPW dynamics of thin‐walled structures by combining Gaussian process regression (GPR) with proper orthogonal decomposition (POD) when IPW dynamics at a large number of cutting positions has to be predicted. The GPR method is used to learn the mapping between a set of the known IPW dynamics and the corresponding cutting positions. POD is used to reduce the order of the matrix assembled by the mode shape vectors at different cutting positions, before the GPR model of the IPW mode shape is established. The computation time of the proposed model is mainly composed of the time taken for predicting a known set of IPW dynamics and the time taken for training GPR models. Simulation shows that the proposed model requires less computation time. Moreover, the accuracy of the proposed model is comparable to that of the existing methods. Comparison between the predicted stability lobe diagram and the experimental results shows that IPW dynamics predicted by the proposed model is accurate enough for predicting the stability of milling of thin‐walled structures.

Topics & Concepts

ComputationStability (learning theory)KrigingProcess (computing)Surrogate modelSet (abstract data type)Gaussian processEngineeringComputer scienceGaussianAlgorithmMachine learningOperating systemQuantum mechanicsPhysicsProgramming languageAdvanced machining processes and optimizationManufacturing Process and OptimizationAdvanced Machining and Optimization Techniques