A homogenously weighted moving average scheme for observations under the effect of serial dependence and measurement inaccuracy

Thanwane, M.; Shongwe, S.; Aslam, M.; Malela-Majika, J.; Albassam, M.

Growing Science » International Journal of Industrial Engineering Computations » A homogenously weighted moving average scheme for observations under the effect of serial dependence and measurement inaccuracy

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International Journal of Industrial Engineering Computations

ISSN 1923-2934 (Online) - ISSN 1923-2926 (Print) Quarterly Publication Volume 12 Issue 4 pp. 401-414 , 2021

A homogenously weighted moving average scheme for observations under the effect of serial dependence and measurement inaccuracy Pages 401-414 Download PDF

Authors: Maonatlala Thanwane, Sandile C. Shongwe, Muhammad Aslam, Jean-Claude Malela-Majika, Mohammed Albassam

DOI: 10.5267/j.ijiec.2021.5.003

Keywords: Autocorrelation, Control chart, Homogeneously weighted moving average (HWMA), Measurement errors, Mixed samples strategy, Multiple measurements, Skipping sampling strategy

Abstract: The combined effect of serial dependency and measurement errors is known to negatively affect the statistical efficiency of any monitoring scheme. However, for the recently proposed homogenously weighted moving average (HWMA) scheme, the research that exists concerns independent and identically distributed observations and measurement errors only. Thus, in this paper, the HWMA scheme for monitoring the process mean under the effect of within-sample serial dependence with measurement errors is proposed for both constant and linearly increasing measurement system variance. Monte Carlo simulation is used to evaluate the run-length distribution of the proposed HWMA scheme. A mixed-s&m sampling strategy is incorporated to the HWMA scheme to reduce the negative effect of serial dependence and measurement errors and its performance is compared to the existing Shewhart scheme. An example is given to illustrate how to implement the proposed HWMA scheme for use in real-life applications.

How to cite this paper

 Thanwane, M., Shongwe, S., Aslam, M., Malela-Majika, J & Albassam, M. (2021). A homogenously weighted moving average scheme for observations under the effect of serial dependence and measurement inaccuracy.International Journal of Industrial Engineering Computations , 12(4), 401-414.

Refrences

Abbas, N. (2020). Homogeneously weighted moving average control chart with an application in substrate manufacturing process. Computers & Industrial Engineering, 120, 460-470. Abbas, N., Riaz, M., Ahmad, S., Abid, M., & Zaman, B. (2020). On the efficient monitoring of multivariate processes with unknown parameters. Mathematics, 8(5), 823. Abid, M., Shabbir, A., Nazir, H.Z., Sherwani, R.A.K., & Riaz, M. (2020a). A double homogeneously weighted moving average control chart for monitoring of the process mean. Quality and Reliability Engineering International, 36(5), 1513-1527. Abid, M., Mei, S., Nazir, H.Z., Riaz, M., & Hussain, S. (2020b). A mixed HWMA-CUSUM mean chart with an application to manufacturing process. Quality and Reliability Engineering International, 37(2), 618-631. Adegoke, N.A., Smith, A.N.H., Anderson, M.J., Sanusi, R.A., & Pawley, M.D.M. (2019a). Efficient homogeneously weighted moving average chart for monitoring process mean using an auxiliary variable. IEEE Access, 7, 94021-94032. Adegoke, N.A., Abbasi, S.A., Smith, A.N.H., Anderson, M.J., & Pawley, M.D.M. (2019b). A multivariate homogeneously weighted moving average control chart. IEEE Access, 7, 9586-9597. Adeoti, O.A., & Koleoso, S.O. (2020). A hybrid homogeneously weighted moving average control chart for process monitoring. Quality and Reliability Engineering International, 36(6), 2170-2186. Ahmad, S., Riaz, M., Hussain, S., & Abbasi, S.A. (2019). On auxiliary information-based control charts for autocorrelated processes with application in manufacturing industry. The International Journal of Advanced Manufacturing Technology, 100(5-8), 1965-1980. Alevizakos, V., Chatterjee, K., & Koukouvinos, C. (2021). The extended homogenously weighted moving average control chart. Quality and Reliability Engineering International, DOI: 10.1002/qre.2849 Alwan, L.C., & Radson, D. (1992). Time-series investigation of subsample mean chart. IIE Transactions, 24(5), 66-80. Arif, F., Noor-ul-Amin, M., & Hanif, M. (2020). Joint monitoring of mean and variance using likelihood ratio test statistic with measurement error. Quality Technology & Quantitative Management, 18(2), 202-224. Asif, F., Khan, S., & Noor-ul-Amin, M. (2020). Hybrid exponentially weighted moving average control chart with measurement error. Iranian Journal of Science and Technology, Transactions A: Science, 44(3), 801-811. Aslam, M., Saghir, A., & Ahmad, L. (2020). Introduction to Statistical Process Control, Hoboken, NJ, USA: Wiley. Costa, A.F.B., & Castagliola, P. (2011). Effect of measurement error and autocorrelation on the X ̅ chart. Journal of Applied Statistics, 38(4), 661-673. Dargopatil, P., & Ghute, V. (2019). New sampling strategies to reduce the effect of autocorrelation on the synthetic T2 chart to monitor bivariate process. Quality and Reliability Engineering International, 35(1), 30-46. Dawod, A., Adegoke, N.A., & Abbasi, S.A. (2020). Efficient linear profile schemes for monitoring bivariate correlated processes with applications in the pharmaceutical industry. Chemometrics and Laboratory Systems, 206, 104137. Franco, B.C., Castagliola, P., Celano, G., & Costa, A.F.B. (2014). A new sampling strategy to reduce the effect of autocorrelation on a control chart. Journal of Applied Statistics, 41(7), 1408-1421. Linna, K.W., & Woodall, W.H. (2001). Effect of measurement error on Shewhart control charts. Journal of Quality Technology, 33(2), 213-222. Maleki, M.R., Amiri, A., & Castagliola, P. (2017). Measurement errors in statistical process monitoring: A literature review. Computers & Industrial Engineering, 103, 316-329. Malela-Majika, J.-C., Shongwe, S.C., & Adeoti, O.A. (2021). A hybrid homogenously weighted moving average control chart for process monitoring: Discussion. Quality and Reliability Engineering International, DOI: 10.1002/qre.2911. Maravelakis, P., Panaretos, J., & Psarakis, S. (2004). EWMA chart and measurement error. Journal of Applied Statistics, 31(4), 445-455. Maravelakis, P. (2012). Measurement error on the CUSUM control chart. Journal of Applied Statistics, 39(2), 323-336. Montgomery, D.C. (2013). Statistical Quality Control: A Modern Introduction, 7th ed., Singapore: John Wiley & Sons. Nawaz, T., & Han, D. (2020). Monitoring the process location by using new ranked set sampling based memory control charts. Quality Technology & Quantitative Management, 17(3), 255-284. Nguyen, H.D., Nguyen, Q.T., Nguyen, T.H., Balakrishnan, N., & Tran, K.P. (2020). The performance of the EWMA median chart in the presence of measurement error. Artificial Intelligence Evolution, 1(1), 48-62. Oh, J., & Weiβ, C.H. (2020). On the individuals chart with supplementary runs rules under serial dependence. Methodology and Computing in Applied Probability, 22, 1257-1273. Prajapati, D.R., & Singh, S. (2012). Control charts for monitoring the autocorrelated process parameters: A literature review. International Journal of Productivity and Quality Management, 10(2), 207-249. Raza, M., Nawaz, T., & Han, D. (2020). On designing distribution-free homogeneously weighted moving average control charts. Journal Testing and Evaluation, 48(4), 3154-3171. Shongwe, S.C., Malela-Majika, J.-C., & Castagliola, P. (2020). The new synthetic and runs-rules schemes to monitor the process mean of autocorrelated observations with measurement errors. Communications in Statistics – Theory and Methods, DOI: 10.1080/03610926.2020.1737125. Shongwe, S.C., & Malela-Majika, J.-C. (2020). A new variable sampling size and interval synthetic and runs-rules schemes to monitor the process mean of autocorrelated observations with measurement errors. International Journal of Industrial Engineering Computations, 11(4), 607-626. Shongwe, S.C., Malela-Majika, J.-C., & Castagliola, P. (2021). A combined mixed-s-skip sampling strategy to reduce the effect of autocorrelation on the X ̅ scheme with and without measurement errors. Journal of Applied Statistics, 48(7), 1243-1268. Thanwane, M., Malela-Majika, J.-C., Castagliola, P., & Shongwe, S.C. (2020). The effect of measurement errors on the performance of the homogeneously weighted moving average X ̅ monitoring scheme. Transactions of the Institute of Measurement and Control, 43(3), 728-745. Xiaohong, L., & Zhaojun, W. (2009). The CUSUM control chart for the autocorrelated data with measurement error. Chinese Journal of Applied Probability, 25(5), 461-474. Yang, S.F., & Yang, C.M. (2005). Effects of imprecise measurement on the two dependent processes control for the autocorrelated observations. The International Journal of Advanced Manufacturing Technology, 26(5-6), 623-630. Zaidi, F., Castagliola, P., Tran, K.P., & Khoo, M.B.C. (2020). Performance of the MEWMA-CoDa control chart in the presence of measurement errors. Quality and Reliability Engineering International, 36(7), 2411-2440.