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A Transfer Learning‐Based Method for Facilitating the Prediction of Unsteady Crystal Growth

Yifan Dang, Kentaro Kutsukake, Xin Liu, Yoshiki Inoue, Xinbo Liu, Shota Seki, Can Zhu, Shunta Harada, Miho Tagawa, Toru Ujihara

2022Advanced Theory and Simulations12 citationsDOI

Abstract

Abstract Real‐time prediction and dynamic control systems that can adapt to an unsteady environment are necessary for material fabrication processes, especially crystal growth. Recent studies have demonstrated the effectiveness of machine learning in predicting an unsteady crystal growth process, but its wider application is hindered by the large amount of training data required for sufficient accuracy. To address this problem, this study investigates the capability of transfer learning to predict geometric evolution in an unsteady silicon carbide (SiC) solution growth system based on a small amount of data. The performance of transferred models is discussed regarding the effect of the transfer learning method, training data amount, and time step length. The transfer learning strategy yields the same accuracy as that of training from scratch but requires only 20% of the training data. The accuracy is stably inherited through successive time steps, which demonstrates the effectiveness of transfer learning in reducing the required amount of training data for predicting evolution in an unsteady crystal growth process. Moreover, the transferred models trained with relatively more data (no more than 100%) further improve the accuracy inherited from the source model through multiple time steps, which broadens the application scope of transfer learning.

Topics & Concepts

Transfer of learningComputer scienceProcess (computing)Scope (computer science)Artificial intelligenceTransfer (computing)Machine learningParallel computingProgramming languageOperating systemMachine Learning in Materials ScienceAdvanced machining processes and optimizationAdvanced Machining and Optimization Techniques