A Meta-Model Architecture and Elimination Method for Uncertainty Modeling

IF 1.5 4区 计算机科学 Q3 COMPUTER SCIENCE, SOFTWARE ENGINEERING IET Software Pub Date : 2024-01-12 DOI:10.1049/2024/5591449
Haoran Shi, Shijun Liu, Li Pan
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Abstract

Uncertainty exists widely in various fields, especially in industrial manufacturing. From traditional manufacturing to intelligent manufacturing, uncertainty always exists in the manufacturing process. With the integration of rapidly developing intelligent technology, the complexity of manufacturing scenarios is increasing, and the postdecision method cannot fully meet the needs of the high reliability of the process. It is necessary to research the pre-elimination of uncertainty to ensure the reliability of process execution. Here, we analyze the sources and characteristics of uncertainty in manufacturing scenarios and propose a meta-model architecture and uncertainty quantification (UQ) framework for uncertainty modeling. On the one hand, our approach involves the creation of a meta-model structure that incorporates various strategies for uncertainty elimination (UE). On the other hand, we develop a comprehensive UQ framework that utilizes quantified metrics and outcomes to bolster the UE process. Finally, a deterministic model is constructed to guide and drive the process execution, which can achieve the purpose of controlling the uncertainty in advance and ensuring the reliability of the process. In addition, two typical manufacturing process scenarios are modeled, and quantitative experiments are conducted on a simulated production line and open-source data sets, respectively, to illustrate the idea and feasibility of the proposed approach. The proposed UE approach, which innovatively combines the domain modeling from the software engineering field and the probability-based UQ method, can be used as a general tool to guide the reliable execution of the process.

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用于不确定性建模的元模型架构和消除方法
不确定性广泛存在于各个领域,尤其是工业制造领域。从传统制造到智能制造,制造过程中始终存在不确定性。随着快速发展的智能技术的融合,制造场景的复杂性不断增加,后决策方法已不能完全满足过程高可靠性的需求。有必要研究如何预先消除不确定性,以确保流程执行的可靠性。在此,我们分析了制造场景中不确定性的来源和特征,并提出了用于不确定性建模的元模型架构和不确定性量化(UQ)框架。一方面,我们的方法包括创建一个元模型结构,其中包含各种消除不确定性(UE)的策略。另一方面,我们开发了一个全面的不确定性消除框架,利用量化指标和结果来支持不确定性消除过程。最后,我们构建了一个确定性模型来指导和驱动流程执行,从而达到提前控制不确定性和确保流程可靠性的目的。此外,还模拟了两种典型的制造流程场景,并分别在模拟生产线和开源数据集上进行了定量实验,以说明所提方法的思路和可行性。所提出的 UE 方法创新性地结合了软件工程领域的领域建模和基于概率的 UQ 方法,可用作指导流程可靠执行的通用工具。
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来源期刊
IET Software
IET Software 工程技术-计算机:软件工程
CiteScore
4.20
自引率
0.00%
发文量
27
审稿时长
9 months
期刊介绍: IET Software publishes papers on all aspects of the software lifecycle, including design, development, implementation and maintenance. The focus of the journal is on the methods used to develop and maintain software, and their practical application. Authors are especially encouraged to submit papers on the following topics, although papers on all aspects of software engineering are welcome: Software and systems requirements engineering Formal methods, design methods, practice and experience Software architecture, aspect and object orientation, reuse and re-engineering Testing, verification and validation techniques Software dependability and measurement Human systems engineering and human-computer interaction Knowledge engineering; expert and knowledge-based systems, intelligent agents Information systems engineering Application of software engineering in industry and commerce Software engineering technology transfer Management of software development Theoretical aspects of software development Machine learning Big data and big code Cloud computing Current Special Issue. Call for papers: Knowledge Discovery for Software Development - https://digital-library.theiet.org/files/IET_SEN_CFP_KDSD.pdf Big Data Analytics for Sustainable Software Development - https://digital-library.theiet.org/files/IET_SEN_CFP_BDASSD.pdf
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