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首页> 外文期刊>Mechanical systems and signal processing >Differentiable neural architecture search augmented with pruning and multi-objective optimization for time-efficient intelligent fault diagnosis of machinery
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Differentiable neural architecture search augmented with pruning and multi-objective optimization for time-efficient intelligent fault diagnosis of machinery

机译:可分解的神经结构搜索,以修剪和多目标优化为时效的智能故障诊断

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摘要

Intelligent fault diagnosis, which is mainly based on neural network, has been widely used in machinery monitoring. Although such deep learning methods are effective, the new architectures are mainly handcrafted by series of experiments that require ample time and substantial efforts. To automate process of building neural networks and save designing time, a novel differentiable neural architecture search method is proposed. By gradually reducing candidate operations while retaining trained parameters during pruning, computation consumed by each stage of neural architecture search is decreased, which accelerates search process. To improve inferential efficiency of subnetworks, specially designed penalty terms are introduced into the objective function for searching optimal numbers of layers and nodes, which can reduce complexity of subnetworks and save calculation time of signal analysis. In addition, exclusive competition between candidate operations is broken by changing discretization and selection methods of operations, which provides a basis for channel fusion. Effectiveness of the proposed method is verified by two datasets. Experiments show that this method can generate subnetworks of lower complexity and less computational cost than other state-of-art neural architecture search techniques, while achieving competitive result.
机译:智能故障诊断主要基于神经网络,已广泛用于机械监测。虽然这种深度学习方法是有效的,但新的架构主要由一系列需要充足的时间和大量努力的一系列实验来手工制作。为了自动构建神经网络的过程并节省设计时间,提出了一种新颖的可分辨性神经结构搜索方法。通过逐步减少候选操作的同时在修剪期间保持训练的参数,可以减少由神经结构搜索的每个阶段消耗的计算,从而加速搜索过程。为了提高子网的推理效率,将专门设计的惩罚术语引入搜索最佳数量和节点的目标函数,这可以降低子网的复杂性并节省信号分析的计算时间。此外,通过改变频道融合的基础,通过改变频道融合的基础来破坏候选操作之间的独家竞争。所提出的方法的有效性由两个数据集验证。实验表明,该方法可以产生比其他最先进的神经结构搜索技术更低的复杂性和计算成本较低的子网,同时实现竞争结果。

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  • 来源
    《Mechanical systems and signal processing》 |2021年第9期|107773.1-107773.19|共19页
  • 作者

    Kaiyu Zhang; Jinglong Chen; Shuilong He; Enyong Xu; Fudong Li; Zitong Zhou;

  • 作者单位

    State Key Laboratory for Manufacturing and Systems Engineering Xi'an Jiaotong University Xi'an 710049 China;

    State Key Laboratory for Manufacturing and Systems Engineering Xi'an Jiaotong University Xi'an 710049 China;

    School of Mechanical and Electrical Engineering Guilin University of Electronic Technology Guilin 541004 China;

    School of Mechanical Science and Engineering Huazhong University of Science and Technology Wuhan 430074 China Dongfeng Liuzhou Motor Co. Ltd. Liuzhou 545005 China;

    State Key Laboratory for Manufacturing and Systems Engineering Xi'an Jiaotong University Xi'an 710049 China;

    State Key Laboratory for Manufacturing and Systems Engineering Xi'an Jiaotong University Xi'an 710049 China;

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  • 原文格式 PDF
  • 正文语种 eng
  • 中图分类
  • 关键词

    Rolling bearing; Deep learning; Neural architecture search; Multi-objective optimization; Network pruning;

    机译:滚动轴承;深度学习;神经结构搜索;多目标优化;网络修剪;

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