Ontologies for prognostics and health management of production systems: overview and research challenges

IF 5.9 2区 工程技术 Q1 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE
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引用次数: 0

Abstract

Prognostics and Health Management (PHM) approaches aim to intervene in the equipment of production systems before faults occur. To properly implement a PHM system, data-centric steps must be taken, including data acquisition and manipulation, detection of machine states, health assessment, prognosis of future failures, and advisory generation. The data generated by different data sources, such as maintenance management systems, equipment manufacturer manuals, design documentation, and process monitoring and control systems, are fundamental for PHM steps. Discovering and using the knowledge embedded in this data is relevant because, for example, data-driven techniques require knowledge, maintenance data often contain tacit knowledge that can facilitate knowledge transfer and collaboration between maintenance personnel with different levels of experience and expertise, and the knowledge related to the same types of systems could be context-dependent. However, the heterogeneity of data sources, the variety of data types, and the possibility of context-dependent data pose challenges in revealing the real value of data and discovering the useful, yet hidden, patterns embedded in maintenance data that can lead to explicit knowledge. Ontologies can effectively contribute to this issue through the organization of data, semantic annotation, integration, and checking of consistency. Several ontologies contributing to the PHM process have been proposed in the scientific literature. However, to the best of our knowledge, no overview of the available ontologies contributing to the PHM steps of production systems is present in the literature. Therefore, this paper aimed to investigate the ontologies and knowledge graphs proposed in the literature for the PHM of production systems. A systematic analysis and mapping of the literature was performed, and the main information was extracted and discussed according to (i) the type and year of the publication, (ii) the ontological and non-ontological resources adopted for designing the ontology/knowledge graph, (iii) the method adopted for implementing the approach, (iv) the type of application, (v) the step(s) of the PHM process on which the article is focused, and (vi) the type of decisions (strategical, tactical, or operational) to which the ontology/knowledge graph is adopted. Subsequently, the conducted analysis led to the definition of a research agenda in the domain, including the following challenges to address: (1) alignment of the ontologies in the maintenance field with respect to top-level ontologies, (2) connection among the different PHM steps at the operational level, (3) major exploitation of the combination of data-driven AI, ontologies, and reasoning for predictive maintenance, and (4) supporting sustainability-related challenges through the connection between the production system, maintenance system, and product.

生产系统预报和健康管理本体论:概述和研究挑战
摘要 诊断和健康管理(PHM)方法旨在故障发生前对生产系统的设备进行干预。要正确实施 PHM 系统,必须采取以数据为中心的步骤,包括数据采集和处理、机器状态检测、健康评估、未来故障预报以及生成建议。不同数据源(如维护管理系统、设备制造商手册、设计文档以及过程监测和控制系统)生成的数据是 PHM 步骤的基础。发现和使用这些数据中蕴含的知识非常重要,因为数据驱动技术需要知识,维护数据通常包含隐性知识,可以促进具有不同经验和专业知识水平的维护人员之间的知识转移和协作,而且与同类系统相关的知识可能与具体情况有关。然而,数据源的异构性、数据类型的多样性以及数据与上下文相关的可能性,都为揭示数据的真正价值、发现蕴藏在维护数据中有用但隐蔽的模式(这些模式可产生显性知识)带来了挑战。本体论可以通过数据组织、语义注释、集成和一致性检查有效地解决这一问题。科学文献中已经提出了一些有助于 PHM 流程的本体论。然而,据我们所知,文献中并没有对有助于生产系统 PHM 步骤的可用本体进行概述。因此,本文旨在研究文献中提出的用于生产系统 PHM 的本体和知识图谱。本文对文献进行了系统分析和映射,并根据以下方面提取和讨论了主要信息:(i) 出版物的类型和年份;(ii) 设计本体/知识图谱时采用的本体和非本体资源;(iii) 实施方法时采用的方法;(iv) 应用类型;(v) 文章重点关注的 PHM 流程步骤;(vi) 采用本体/知识图谱的决策类型(战略、战术或操作)。随后,通过分析确定了该领域的研究议程,包括以下需要应对的挑战:(1) 将维护领域的本体与顶层本体相统一,(2) 在操作层面上将不同的公共健康管理步骤联系起来,(3) 主要利用数据驱动的人工智能、本体和推理相结合来进行预测性维护,以及 (4) 通过生产系统、维护系统和产品之间的联系来支持与可持续性相关的挑战。
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 Intelligent Manufacturing
Journal of Intelligent Manufacturing 工程技术-工程:制造
CiteScore
19.30
自引率
9.60%
发文量
171
审稿时长
5.2 months
期刊介绍: The Journal of Nonlinear Engineering aims to be a platform for sharing original research results in theoretical, experimental, practical, and applied nonlinear phenomena within engineering. It serves as a forum to exchange ideas and applications of nonlinear problems across various engineering disciplines. Articles are considered for publication if they explore nonlinearities in engineering systems, offering realistic mathematical modeling, utilizing nonlinearity for new designs, stabilizing systems, understanding system behavior through nonlinearity, optimizing systems based on nonlinear interactions, and developing algorithms to harness and leverage nonlinear elements.
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