Multibranch Block-Based Grain Size Classification Of Hybrid Disk Using Ultrasonic Scattering: A Deep Learning Method

IF 0.5 4区材料科学 Q4 MATERIALS SCIENCE, CHARACTERIZATION & TESTING

Materials Evaluation Pub Date : 2024-04-01 DOI:10.32548/2024.me-04388

Xiao Liu, Zheng-xiao Sha, Jing Liang

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引用次数: 0

Abstract

To assess the grain size of hybrid disks, we propose a simple network architecture—the wide-paralleled convolutional neural network (WP-CNN)—based solely on multibranch blocks and create a grain size classification model based on it. Multibranch blocks are used to enhance the capability of feature extraction, and the global average pooling layer was implemented to reduce the number of model parameters. To train and test the model, a dataset of ultrasonic scattering signals from a hybrid disk was constructed. The WP-CNN structure and hyperparameter selection were examined using the training set. The experiment demonstrated that, compared to traditional 1D convolutional neural network, 1D ResNet, and InceptionTime, the classification accuracy of this method can reach 92.3%. A comparison is made with the empirical mode decomposition scattering model and frequency spectra tree model. The proposed network provides accurate classification of grain size without physical parameters and specific physical models. The results show the deep learning method has the feasibility to evaluate hybrid disk grain size distribution.

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利用超声波散射对混合盘进行基于多分支块的粒度分类：一种深度学习方法

为了评估混合磁盘的粒度，我们提出了一种仅基于多分支块的简单网络架构--宽平行卷积神经网络（WP-CNN），并在此基础上创建了粒度分类模型。多分支块用于增强特征提取能力，全局平均池化层用于减少模型参数数量。为了训练和测试模型，构建了一个混合盘超声散射信号数据集。利用训练集检验了 WP-CNN 结构和超参数选择。实验表明，与传统的一维卷积神经网络、一维 ResNet 和 InceptionTime 相比，该方法的分类准确率可达 92.3%。实验还与经验模态分解散射模型和频谱树模型进行了比较。在没有物理参数和特定物理模型的情况下，所提出的网络能对粒度进行准确分类。结果表明，深度学习方法具有评估混合盘粒度分布的可行性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Materials Evaluation 工程技术-材料科学：表征与测试

CiteScore

0.90

自引率

16.70%

发文量

审稿时长

6-12 weeks

期刊介绍： Materials Evaluation publishes articles, news and features intended to increase the NDT practitioner’s knowledge of the science and technology involved in the field, bringing informative articles to the NDT public while highlighting the ongoing efforts of ASNT to fulfill its mission. M.E. is a peer-reviewed journal, relying on technicians and researchers to help grow and educate its members by providing relevant, cutting-edge and exclusive content containing technical details and discussions. The only periodical of its kind, M.E. is circulated to members and nonmember paid subscribers. The magazine is truly international in scope, with readers in over 90 nations. The journal’s history and archive reaches back to the earliest formative days of the Society.

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