A deep attention based approach for predictive maintenance applications in IoT scenarios

IF 7.3 2区 工程技术 Q1 ENGINEERING, INDUSTRIAL
Roberto De Luca, Antonino Ferraro, Antonio Galli, M. Gallo, V. Moscato, Giancarlo Sperlí
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引用次数: 2

Abstract

PurposeThe recent innovations of Industry 4.0 have made it possible to easily collect data related to a production environment. In this context, information about industrial equipment – gathered by proper sensors – can be profitably used for supporting predictive maintenance (PdM) through the application of data-driven analytics based on artificial intelligence (AI) techniques. Although deep learning (DL) approaches have proven to be a quite effective solutions to the problem, one of the open research challenges remains – the design of PdM methods that are computationally efficient, and most importantly, applicable in real-world internet of things (IoT) scenarios, where they are required to be executable directly on the limited devices’ hardware.Design/methodology/approachIn this paper, the authors propose a DL approach for PdM task, which is based on a particular and very efficient architecture. The major novelty behind the proposed framework is to leverage a multi-head attention (MHA) mechanism to obtain both high results in terms of remaining useful life (RUL) estimation and low memory model storage requirements, providing the basis for a possible implementation directly on the equipment hardware.FindingsThe achieved experimental results on the NASA dataset show how the authors’ approach outperforms in terms of effectiveness and efficiency the majority of the most diffused state-of-the-art techniques.Research limitations/implicationsA comparison of the spatial and temporal complexity with a typical long-short term memory (LSTM) model and the state-of-the-art approaches was also done on the NASA dataset. Despite the authors’ approach achieving similar effectiveness results with respect to other approaches, it has a significantly smaller number of parameters, a smaller storage volume and lower training time.Practical implicationsThe proposed approach aims to find a compromise between effectiveness and efficiency, which is crucial in the industrial domain in which it is important to maximize the link between performance attained and resources allocated. The overall accuracy performances are also on par with the finest methods described in the literature.Originality/valueThe proposed approach allows satisfying the requirements of modern embedded AI applications (reliability, low power consumption, etc.), finding a compromise between efficiency and effectiveness.
物联网场景下基于深度关注的预测性维护应用方法
目的工业4.0的最新创新使收集与生产环境相关的数据成为可能。在这种情况下,通过应用基于人工智能(AI)技术的数据驱动分析,通过适当的传感器收集的工业设备信息可以有益地用于支持预测性维护(PdM)。尽管深度学习(DL)方法已被证明是解决该问题的非常有效的方法,但开放研究的挑战之一仍然存在——设计计算高效的PdM方法,最重要的是,这些方法适用于现实世界的物联网(IoT)场景,在这些场景中,它们需要直接在有限的设备硬件上执行。设计/方法论/方法在本文中,作者提出了一种用于PdM任务的DL方法,该方法基于一种特殊且非常有效的体系结构。所提出的框架背后的主要新颖性是利用多头注意力(MHA)机制来获得剩余使用寿命(RUL)估计方面的高结果和低内存模型存储要求,为直接在设备硬件上实现提供了可能的基础。发现在NASA数据集上获得的实验结果表明,作者的方法在有效性和效率方面优于大多数最先进的技术。研究局限性/含义还对NASA数据集的空间和时间复杂性与典型的长短期记忆(LSTM)模型和最先进的方法进行了比较。尽管与其他方法相比,作者的方法取得了类似的有效性结果,但它的参数数量明显较少,存储容量较小,训练时间较短。实际含义所提出的方法旨在找到有效性和效率之间的折衷方案,这在工业领域至关重要,在工业领域,最大限度地提高所获得的绩效和分配的资源之间的联系很重要。整体精度性能也与文献中描述的最佳方法不相上下。独创性/价值所提出的方法可以满足现代嵌入式人工智能应用程序的要求(可靠性、低功耗等),在效率和有效性之间找到折衷方案。
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 Manufacturing Technology Management
Journal of Manufacturing Technology Management Engineering-Control and Systems Engineering
CiteScore
16.30
自引率
7.90%
发文量
45
期刊介绍: The Journal of Manufacturing Technology Management (JMTM) aspires to be the premier destination for impactful manufacturing-related research. JMTM provides comprehensive international coverage of topics pertaining to the management of manufacturing technology, focusing on bridging theoretical advancements with practical applications to enhance manufacturing practices. JMTM seeks articles grounded in empirical evidence, such as surveys, case studies, and action research, to ensure relevance and applicability. All submissions should include a thorough literature review to contextualize the study within the field and clearly demonstrate how the research contributes significantly and originally by comparing and contrasting its findings with existing knowledge. Articles should directly address management of manufacturing technology and offer insights with broad applicability.
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