Simultaneous monitoring of the mean vector and covariance matrix of multivariate multiple linear profiles with a new adaptive Shewhart-type control chart

IF 1.3 4区工程技术 Q4 ENGINEERING, INDUSTRIAL

Quality Engineering Pub Date : 2023-01-13 DOI:10.1080/08982112.2022.2164725

H. Sabahno, A. Amiri

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引用次数: 2

Abstract

Abstract There has been a growing interest in research regarding monitoring a process through a regression model (called a profile) rather than a simple quality characteristic. This paper proposes a new monitoring scheme to simultaneously monitor the multivariate multiple linear profiles’ parameters. This scheme is based on the Shewhart control chart concept and only has one single (max-type) control chart for monitoring regression coefficients and error’s variation, which uses a new statistic to improve the variability (error’s variance-covariance matrix) shift detection in multivariate profiles. To increase the sensitivity and capability of the proposed scheme, especially in detecting small to moderate shift sizes, we add a variable parameters (VP) adaptive scheme to the developed control chart as well, considering that no adaptive monitoring schemes have so far been developed for monitoring the multivariate multiple linear profiles and neither are there any VP adaptive features for all profile monitoring schemes. Next, we develop a Markov chain model to compute the time to signal and run length performance measures. After that, we perform extensive numerical analyses to first compare the proposed control chart with the best available control charts and then evaluate its performance under different shift scenarios as well as different dimensions. The results show that the new monitoring scheme performs well compared to the best available monitoring schemes, and more importantly, it is more applicable in real practice. Finally, an illustrative example is presented to show the implementation of the proposed scheme in practice.

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用一种新的自适应Shewhart型控制图同时监测多元线性剖面的均值向量和协方差矩阵

通过回归模型(称为配置文件)而不是简单的质量特征来监测过程的研究日益引起人们的兴趣。本文提出了一种同时监测多变量多线性剖面参数的新方案。该方案基于Shewhart控制图的概念，只有一个单一的(max-type)控制图来监测回归系数和误差的变化，并使用了一种新的统计量来提高多变量剖面的可变性(误差方差-协方差矩阵)偏移检测。考虑到目前为止还没有开发出用于监测多变量线性曲线的自适应监测方案，并且也没有任何VP自适应特征适用于所有曲线监测方案，为了提高所提出方案的灵敏度和能力，特别是在检测小到中等位移大小方面，我们还在所开发的控制图中添加了一个变参数(VP)自适应方案。接下来，我们开发了一个马尔可夫链模型来计算信号时间和运行长度性能指标。之后，我们进行了广泛的数值分析，首先将所提出的控制图与最佳可用控制图进行比较，然后评估其在不同班次场景和不同维度下的性能。结果表明，与现有的最佳监控方案相比，新方案性能良好，更具有实际应用价值。最后，通过一个实例说明了该方案在实际应用中的实现情况。

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

Quality Engineering ENGINEERING, INDUSTRIAL-STATISTICS & PROBABILITY

CiteScore

3.90

自引率

10.00%

发文量

审稿时长

>12 weeks

期刊介绍： Quality Engineering aims to promote a rich exchange among the quality engineering community by publishing papers that describe new engineering methods ready for immediate industrial application or examples of techniques uniquely employed. You are invited to submit manuscripts and application experiences that explore: Experimental engineering design and analysis Measurement system analysis in engineering Engineering process modelling Product and process optimization in engineering Quality control and process monitoring in engineering Engineering regression Reliability in engineering Response surface methodology in engineering Robust engineering parameter design Six Sigma method enhancement in engineering Statistical engineering Engineering test and evaluation techniques.