Frequency-Focused Sound Data Generator for Fault Diagnosis in Industrial Robots

IF 4.8 2区工程技术 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Journal of Computational Design and Engineering Pub Date : 2024-07-04 DOI:10.1093/jcde/qwae061

Semin Ahn, Jinoh Yoo, Kyu-Wha Lee, B. D. Youn, Sung-Hoon Ahn

引用次数: 0

Abstract

A frequency-focused sound data generator was developed for the in-situ fault sound diagnosis of industrial robot reducers. The sound data generator, based on a conditional generative adversarial network, selects a target frequency range without relying on domain knowledge. A sound dataset of normal and faulty harmonic drive rotations of in-situ industrial robots was collected using an attachable wireless sound sensor. The generated sound data were evaluated based on the fault diagnosis accuracy of a simple classifier trained using the generated data and tested using real data. The proposed method well-defined the frequency feature clusters and produced high-quality data, exhibiting up to 16.0% higher precision score on normal and 13.0% higher accuracy on weak-fault harmonic drive compared to the conventional methods, achieving fault diagnosis accuracy of 95.6% even in situations of fault data comprising only 5% of the normal data.

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用于工业机器人故障诊断的频率聚焦声音数据发生器

为对工业机器人减速器进行现场故障声音诊断，开发了一种以频率为重点的声音数据生成器。声音数据生成器基于条件生成式对抗网络，无需依赖领域知识即可选择目标频率范围。使用可连接的无线声音传感器收集了现场工业机器人正常和故障谐波驱动旋转的声音数据集。根据使用生成数据训练的简单分类器的故障诊断准确率对生成的声音数据进行了评估，并使用真实数据进行了测试。与传统方法相比，所提出的方法很好地定义了频率特征簇，并生成了高质量的数据，对正常谐波驱动的精确度提高了 16.0%，对弱故障谐波驱动的精确度提高了 13.0%，即使在故障数据仅占正常数据 5%的情况下，故障诊断精确度也达到了 95.6%。

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

Journal of Computational Design and Engineering Computer Science-Human-Computer Interaction

CiteScore

7.70

自引率

20.40%

发文量

125

期刊介绍： Journal of Computational Design and Engineering is an international journal that aims to provide academia and industry with a venue for rapid publication of research papers reporting innovative computational methods and applications to achieve a major breakthrough, practical improvements, and bold new research directions within a wide range of design and engineering: • Theory and its progress in computational advancement for design and engineering • Development of computational framework to support large scale design and engineering • Interaction issues among human, designed artifacts, and systems • Knowledge-intensive technologies for intelligent and sustainable systems • Emerging technology and convergence of technology fields presented with convincing design examples • Educational issues for academia, practitioners, and future generation • Proposal on new research directions as well as survey and retrospectives on mature field.