人工神经网络在烧结batio3陶瓷密度上的应用

IF 1.4 4区 材料科学 Q3 MATERIALS SCIENCE, CERAMICS
B. Randjelovic, S. Ribar, V. Mitić, Bojana Markovic, H. Fecht, B. Vlahovic
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引用次数: 0

摘要

确定固结陶瓷样品的微观结构参数对微电子微型化和集成化具有重要意义。因此,控制、预测和设计陶瓷材料?在烧结科学中,性能是陶瓷材料巩固过程中的目标。为了在晶粒水平上计算所需的微观结构参数的精确值?基于对大量样品的测量,我们应用人工神经网络作为映射输入-输出数据的强大数学工具。输入信号向前传播,以及贡献计算输出信号的可调系数,表示为误差,它向后传播并被检测参数取代。在我们之前的研究中,我们使用神经网络计算了晶界纳米级的不同电物理参数,如相对电容、击穿电压或切线损耗,现在我们将研究扩展到烧结材料?S密度计算。网络输出上的误差被在块体上测量的不同固结样品密度值所取代,从而能够精确计算材料?层间S密度值。我们根据实验陶瓷材料?S密度=5.4 × 103[kg/m3],但它也为神经网络在其他密度值下的应用开辟了可能性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Artificial neural network applied on sintered BaTiO3-ceramic density
It is very important to determine microstructure parameters of consolidated ceramic samples, because it opens new frontiers for further microelectronics miniaturization and integrations. Therefore, controlling, predicting and designing the ceramic materials? properties are the objectives in ceramic materials consolidating process, within the science of sintering. In order to calculate the precise values of desired microstructure parameter at the level of the grains? coating layers based on the measurements on the bulk samples, we applied the artificial neural networks, as a powerful mathematical tool for mapping input-output data. Input signals are propagated forward, as well as the adjustable coefficients that contribute the calculated output signal, denoted as error, which is propagated backwards and replaced by examined parameter. In our previous research, we used neural networks to calculate different electrophysical parameters at the nano level of the grain boundary, like relative capacitance, breakdown voltage or tangent loss, and now we extend the research on sintered material?s density calculation. Errors on the network output were substituted by different consolidated samples density values measured on the bulk, thus enabling the calculation of precise material?s density values between the layers. We performed the neural network theoretical experiments for different number of neurons in hidden layers, according to experimental ceramics material?s density of ?=5.4x103[kg/m3], but it opens the possibility for neural networks application within other density values, as well.
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来源期刊
Science of Sintering
Science of Sintering 工程技术-材料科学:硅酸盐
CiteScore
2.50
自引率
46.70%
发文量
20
审稿时长
3.3 months
期刊介绍: Science of Sintering is a unique journal in the field of science and technology of sintering. Science of Sintering publishes papers on all aspects of theoretical and experimental studies, which can contribute to the better understanding of the behavior of powders and similar materials during consolidation processes. Emphasis is laid on those aspects of the science of materials that are concerned with the thermodynamics, kinetics and mechanism of sintering and related processes. In accordance with the significance of disperse materials for the sintering technology, papers dealing with the question of ultradisperse powders, tribochemical activation and catalysis are also published. Science of Sintering journal is published four times a year. Types of contribution: Original research papers, Review articles, Letters to Editor, Book reviews.
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