Hybrid physics-embedded recurrent neural networks for fault diagnosis under time-varying conditions based on multivariate proprioceptive signals

IF 8 1区工程技术 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Advanced Engineering Informatics Pub Date : 2024-10-01 DOI:10.1016/j.aei.2024.102851

Rourou Li, Tangbin Xia, Feng Luo, Yimin Jiang, Zhen Chen, Lifeng Xi

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引用次数: 0

Abstract

Accurate fault diagnosis for industrial robots is imperative to improve their availability. Proprioceptive signals collected by intrinsic sensors of robot joint servo drive systems provide a nonintrusive and promising way for practical in-situ diagnosis. However, they generally exhibit significant non-stationarity owing to time-varying operation conditions and limited sampling frequencies constrained by system hardware, which poses challenges in fault signature identification. Thus, a hybrid physics-embedded recurrent neural network is proposed for robot fault diagnosis under variable operation conditions based on proprioceptive signals. It embeds robot governing ordinary differential equations (ODE) as an inductive bias to account for known dynamics. Concurrently, tailored neural networks (NN) are leveraged to compensate for unmodeled dynamics residuum and unmeasurable health states, efficiently extending the hypothesis space. Hereinto, system status-represented latent space inferred from observations is comprehensively regularized by state reconstruction, fault classification, and Fisher discrimination losses to promote state representability and class distinguishability. Furthermore, a bilinear layer-based NN is constructed to statistically model intrinsic nonlinearities simplified away by physical models. Finally, the model-based and data-driven components are synergistically integrated by a differentiable ODE solver to form an end-to-end trainable framework. The superiority of the presented method is illustrated through the simulated and in-situ industrial robot datasets.

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基于多变量本体感觉信号的混合物理嵌入式递归神经网络，用于时变条件下的故障诊断

要提高工业机器人的可用性，就必须对其进行精确的故障诊断。机器人关节伺服驱动系统的固有传感器收集的感知信号为实际现场诊断提供了一种非侵入式的可行方法。然而，由于运行条件随时间变化，系统硬件限制了有限的采样频率，这些信号通常表现出明显的非稳态性，这给故障特征识别带来了挑战。因此，本文提出了一种基于本体感觉信号的混合物理嵌入式递归神经网络，用于可变运行条件下的机器人故障诊断。它嵌入了机器人治理常微分方程（ODE）作为归纳偏置，以考虑已知动态。同时，利用定制的神经网络（NN）来补偿未建模的动态残留和不可测量的健康状态，从而有效地扩展了假设空间。在此基础上，通过状态重构、故障分类和费雪分辨损失对从观测结果中推断出的系统状态表示潜空间进行全面正则化，以提高状态可表示性和类别可区分性。此外，还构建了基于双线性层的 NN，以便对物理模型所简化的内在非线性进行统计建模。最后，基于模型的部分和数据驱动的部分通过一个可微分的 ODE 求解器协同整合，形成一个端到端的可训练框架。通过模拟和现场工业机器人数据集，说明了所介绍方法的优越性。

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

Advanced Engineering Informatics 工程技术-工程：综合

CiteScore

12.40

自引率

18.20%

发文量

292

审稿时长

45 days

期刊介绍： Advanced Engineering Informatics is an international Journal that solicits research papers with an emphasis on 'knowledge' and 'engineering applications'. The Journal seeks original papers that report progress in applying methods of engineering informatics. These papers should have engineering relevance and help provide a scientific base for more reliable, spontaneous, and creative engineering decision-making. Additionally, papers should demonstrate the science of supporting knowledge-intensive engineering tasks and validate the generality, power, and scalability of new methods through rigorous evaluation, preferably both qualitatively and quantitatively. Abstracting and indexing for Advanced Engineering Informatics include Science Citation Index Expanded, Scopus and INSPEC.