A novel approach for Tool-Narayanaswamy-Moynihan model parameter extraction using multi-scale neural model

IF 4.3 3区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY
Marek Pakosta , Petr Dolezel , Roman Svoboda
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Abstract

The accurate determination of parameters in the Tool-Narayanaswamy-Moynihan (TNM) model, which describes the viscoelastic behavior of glass-forming materials, is crucial for predicting material responses through various thermal histories. Traditional methods rely heavily on curve-fitting techniques; however, these often fail due to noise in the data. Furthermore, traditional methods are computationally intensive and prone to inaccuracies, particularly when dealing with complex datasets or when the initial parameter guesses are far from optimal; also, they require a skilled personnel.
In this study, we propose the application of a multi-scale convolutional neural network (MCNN) as a machine learning approach to address these challenges. The MCNN model is trained on a comprehensive simulated dataset encompassing a wide range of TNM parameters, allowing it to learn intricate patterns and dependencies within the data that are difficult to capture with conventional methods. Our results show that the MCNN significantly improves the accuracy of the parameter estimations for β and x across the entire spectrum of tested conditions, achieving performance that is not only comparable to, but often surpasses, traditional curve-fitting methods. Furthermore, the MCNN demonstrates superior robustness when initial parameter estimates are suboptimal or when the dataset exhibits significant noise. Although the prediction accuracy for the activation energy Δh and the pre-exponential factor log(A) was somewhat lower, the method still provides valuable estimates that can be refined with supplementary techniques.
This work highlights the potential of machine learning approaches like MCNN to revolutionize the parameter extraction process in complex physical models, reducing the reliance on manual curve-fitting and providing a more automated, scalable solution. We also analyze the primary sources of prediction errors in the MCNN outputs and offer insights into future improvements, including model architecture refinements and the integration of additional physical constraints. Our findings suggest that this approach can be extended to other domains where similar models are employed, paving the way for broader applications of machine learning in materials science.

Abstract Image

利用多尺度神经模型提取 Tool-Narayanaswamy-Moynihan 模型参数的新方法
Tool-Narayanaswamy-Moynihan (TNM) 模型描述了玻璃成型材料的粘弹性行为,准确确定该模型的参数对于预测材料在各种热历史条件下的响应至关重要。传统方法在很大程度上依赖于曲线拟合技术;然而,由于数据中存在噪声,这些方法往往会失败。此外,传统方法计算量大,容易出现误差,特别是在处理复杂数据集或初始参数猜测远非最优时;而且,这些方法需要熟练的人员。在本研究中,我们提出应用多尺度卷积神经网络(MCNN)作为机器学习方法来应对这些挑战。MCNN 模型是在包含各种 TNM 参数的综合模拟数据集上进行训练的,这使它能够学习到传统方法难以捕捉的数据中错综复杂的模式和依赖关系。我们的研究结果表明,MCNN 显著提高了在所有测试条件下对β和x 参数估计的准确性,其性能不仅可与传统的曲线拟合方法相媲美,而且往往超过后者。此外,当初始参数估计不理想或数据集出现明显噪声时,MCNN 也表现出了卓越的鲁棒性。虽然活化能Δh∗ 和前指数因子 log(A) 的预测准确率略低,但该方法仍能提供有价值的估计值,并可通过辅助技术加以完善。这项工作凸显了 MCNN 等机器学习方法在彻底改变复杂物理模型参数提取过程方面的潜力,减少了对人工曲线拟合的依赖,提供了更加自动化、可扩展的解决方案。我们还分析了 MCNN 输出中预测误差的主要来源,并对未来的改进提出了见解,包括模型架构的完善和额外物理约束条件的整合。我们的研究结果表明,这种方法可以扩展到采用类似模型的其他领域,为机器学习在材料科学领域的更广泛应用铺平道路。
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来源期刊
Materials Chemistry and Physics
Materials Chemistry and Physics 工程技术-材料科学:综合
CiteScore
8.70
自引率
4.30%
发文量
1515
审稿时长
69 days
期刊介绍: Materials Chemistry and Physics is devoted to short communications, full-length research papers and feature articles on interrelationships among structure, properties, processing and performance of materials. The Editors welcome manuscripts on thin films, surface and interface science, materials degradation and reliability, metallurgy, semiconductors and optoelectronic materials, fine ceramics, magnetics, superconductors, specialty polymers, nano-materials and composite materials.
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