Robust Tukey–CUSUM Control Chart for Process Monitoring

Khaliq, Qurat-Ul-Ain; Riaz, Muhammad

doi:10.1002/qre.1804

Cited by 20 publications

(16 citation statements)

References 28 publications

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“…The data sets: The data generated the MA, MME, MEM, MA-TCC, MEM-TCC, and MME-TCC control charts from equations (5), (7), (9), (12), (13), (14) and (15) as shown in graphical results as Figures 5-6. For this case study, the set of data that had the normal distribution showed that the proposed chart was able to detect the change from the 5 th , the MME and MEM-TCC charts were able to detect at 6 th , the MEM chart can be detected at 7 th , the MA and MA-TCC charts were able to detect at 27 th .…”

Section: A the Diameter Of The Workpiece From An Industrial Factorymentioning

confidence: 99%

“…However, it depended on set the parameter of each control chart. Besides, the researchers compared ARL performance of proposed MME-TCC chart vs. Tukey-EWMA [16], Tukey-CUSUM [15] and Tukey EWMA-CUSUM [17] charts under the Normal (0,1) distribution, ARL0 =370 and the numerical ARL1 where  is a shift sizes: 4.00 4.00  −   . The numerical results found the performance of the proposed chart performed better than the Tukey-EWMA, Tukey-CUSUM and Tukey EWMA-CUSUM charts for all magnitudes of change, except for at  = 0.25, the Tukey EWMA-CUSUM performed better than the proposed chart.…”

Section:  mentioning

confidence: 99%

“…In 2012, Sukparungsee [14] studied the strength of TCC for the data with normal and non-normal distributions and found that TCC had better efficiency to detect the larger changes than Shewhart's chart and EWMA. Then, in 2014, Khaliq and Riaz [15] proposed the Tukey-Cumulative Control Chart (TCC-CUSUM) to detect the change of average when the process had the symmetric and asymmetric distribution. The proposed control chart had higher efficiency in detecting the change than TCC and CUSUM.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

A New Nonparametric Tukey MA-EWMA Control Charts for Detecting Mean Shifts

2020

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Section: A the Diameter Of The Workpiece From An Industrial Factorymentioning

confidence: 99%

Section:  mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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A New Nonparametric Tukey MA-EWMA Control Charts for Detecting Mean Shifts

2020

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“…This design is a good alternate to classical EWMA, when data follows a skewed distribution. Khaliq and Riaz [16] designed the CUSUM structure of Tukey chart for small and sustained shifts. This design is best alternate to classical CUSUM chart, when data follow the skewed distribution.…”

Section: Saithanu At Elmentioning

confidence: 99%

On the Performance of Median Based Tukey and Tukey-EWMA Charts Under Rational Subgrouping

et al. 2019

Self Cite

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Control chart (CC) is used to monitor the special causes that arise during the process monitoring.These special causes produce continual shifts in the process parameters that last until it is identified and removed. There is a need for such techniques, which present the true representation of the entire process. Rational subgrouping is an essential concept in Statistical Process Control (SPC) which is seldom overlooked by the practitioner. Hence, most of the manufacturing, engineering, and production processes give output products in the form of batches over smaller intervals of time. The aim of this study is to provide a median based design for Tukey and Tukey-EWMA control charts under subgrouping. It will use the idea of boxplot to monitor the process behavior. This study also provides a brief discussion regarding selecting and forming subgroups from the process data. The performance of the median based Tukey and Tukey-EWMA charts are judged using Average, Median and Standard-Deviation run-length as performance measures. We have considered subgroup sizes of m=1,5 &10 at pre-specified ARL0 equal to 370. To real-life applications of the median based tukey designs are also presented to show their implementation in food manufacturing and hard-bake processes.2

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“…Recently, Raji et al have considered different robust estimators of the process mean and then used them to construct DCUSUM charts for monitoring the process mean when the probability distribution of the underlying quality characteristic is not normal. For more related works on the CUSUM charts, the readers are referred to Waldmann, Jiang et al, Wu et al, Jiang et al, Shu et al, Riaz et al, Abbasi et al, Calzada and Scariano, Nazir et al, Zaman et al, Haq et al, Khaliq and Riaz, Riaz et al, Zaman et al, Abid et al, Faisal et al, and the references cited therein.…”

Section: Introductionmentioning

confidence: 99%

A new dual CUSUM mean chart

Haq

Bibi

2019

Quality & Reliability Eng

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The conventional cumulative sum (CUSUM) chart is usually designed based on a known shift size. In usual practice, shift size is often unknown and can be assumed to vary within an interval. With such a range of shift size, the dual CUSUM (DCUSUM) chart provides more sensitivity than the CUSUM chart. In this paper, we propose dual Crosier CUSUM (DCCUSUM) charts with and without fast initial response features to efficiently monitor the infrequent changes in the mean of a normally distributed process. Monte Carlo simulations are used to compute the run length characteristics of one‐sided and two‐sided DCCUSUM charts. These run length characteristics are compared with those of the CUSUM, Crosier CUSUM, Shewhart‐CUSUM, and DCUSUM charts in terms of the integral relative average run length. It turns out that the proposed chart shows better performance when detecting a range of mean shift sizes. A real dataset is considered to illustrate the implementation of existing and proposed charts.

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Robust Tukey–CUSUM Control Chart for Process Monitoring

Cited by 20 publications

References 28 publications

A New Nonparametric Tukey MA-EWMA Control Charts for Detecting Mean Shifts

A New Nonparametric Tukey MA-EWMA Control Charts for Detecting Mean Shifts

On the Performance of Median Based Tukey and Tukey-EWMA Charts Under Rational Subgrouping

A new dual CUSUM mean chart

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