Authors: O. Ikpotokin

Abstract:

In any production process, every product is aimed to attain a certain standard, but the presence of assignable cause of variability affects our process, thereby leading to low quality of product. The ability to identify and remove this type of variability reduces its overall effect, thereby improving the quality of the product. In case of a univariate control chart signal, it is easy to detect the problem and give a solution since it is related to a single quality characteristic. However, the problems involved in the use of multivariate control chart are the violation of multivariate normal assumption and the difficulty in identifying the quality characteristic(s) that resulted in the out of control signals. The purpose of this paper is to examine the use of non-parametric control chart (the bootstrap approach) for obtaining control limit to overcome the problem of multivariate distributional assumption and the p-value method for detecting out of control signals. Results from a performance study show that the proposed bootstrap method enables the setting of control limit that can enhance the detection of out of control signals when compared, while the p-value method also enhanced in identifying out of control variables.

Keywords: Bootstrap control limit, p-value method, out-of-control signals, p-value, quality characteristics.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1316179

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 954

References:

[1] M. Riaz, “Monitoring Process Variability using Auxiliary Information,” Computational Statistics, vol. 23(2), pp. 253-276, 2008
[2] A.M. Polansky, “A General Framework of Constructing Control Chart,” Quality and Reliability Engineering International, vol. 21(6), pp. 633-653, 2005
[3] M. Huskova, and C. Kirch, “Bootstrapping Sequential Change-point Tests for Linear Regression,” Metrika, vol. 75, pp. 673-708, 2010
[4] C.W. Champ, L.A. Jones-Farmer and S.E. Rigdon, “Properties of the T2 Control Chart when Parameters are Estimated,” Technometrics, vol. 47(4), pp. 437-445, 2005
[5] S. Bersimis, S. Psarakis and J. Panaretos, “Multivariate Statistical Process Control Charts,” Quality and Reliability Engineering International, vol. 23, pp 517 – 543, 2007
[6] Y.M. Chou, R.L. Manson, and J.C. Young, “The Control Chart for Individual Observations from a Multivariate Non-normal Distribution,” Communications in Statistics Simulation and Computation,” vol. 30(8-9), pp. 1937-1949, 2001
[7] S. Chatterjee and P. Qiu, “Distribution-Free Cumulative Sum Control Charts using Bootstrap Based Control Limits,” The Annals of Applied Statistics, vol. 3(1), pp. 349-369, 2009.
[8] P. Phaladiganon, S. B. Kim, V.C.P. Chen, J.G. Baek and S.K. Park, “Bootstrap Based T2 Multivariate Control Charts,” Communication in Statistics-Simulation and Computation, vol.40(5), pp.645-662, 2011
[9] J.A. Adewara and K.S. Adekeye, “Bootstrap Technique for Minimax Multivariate Control Chart,” Open Journal of Statistics, vol. 2, pp. 469-473, 2012
[10] M. H. Balali, N. Nouri and E. Pakdamanian, “Application of the Minimax Control Chart for Multivariate Manufacturing Process,” International Research Journal of Applied and Basic Sciences, vol. 4 Issue 3, pp. 654-661, 2013
[11] A. A. Kalgonda, “Bootstrap Control Limits for Multivariate Auocorrelated Processes,” Journal of Academic and Industrial Research, vol. 1(12), pp. 700-702, 2013
[12] A. Gandy, and J. T. Kvaloy, “Guaranteed Conditional Performance of Control Charts via Bootstrap Methods,” Scandinavian Journal of Statistics, vol. 40 (4), pp. 647-668, 2013
[13] G. C. Runger, F. B. Alt, and D. C. Montgomery, “Contributors to a Multivariate Statistical Process Control Signal,” Communication in Statistics: Theory and Methods, vol. 25(10), pp. 2203–2213, 1996
[14] R.L. Mason, N. D. Tracy and J.C. Young, “Decomposition of Multivariate Control Chart Interpretation,” Journal of Quality Technology, vol. 27, pp. 99-108, 1995
[15] R. Guh, “On Line Identification and Qualification of Mean Shifts in Bivariate Process using a Neural Network based Approach,” Quality and Reliability Engineering International, vol. 23(3), pp. 367- 385, 2007
[16] A. A. Kalagonda, and S. R. Kulkarni, “Diagnosis of Multivariate Control Chart Signal based on Dummy Variable Regression Technique,” Communications in Statistics Theory and Methods, vol. 32(8), pp. 1665-1684, 2003
[17] T. García, M. Vásquez, G, Ramírez, and C. Pérez, “A Methodology to Interpret Multivariate T 2 Control Chart Signals,” Proceedings 59th ISI World Statistics Congress, Hong Kong (Session CPS105), pp. 4553 – 4558, 2013
[18] O. Ikpotokin, and C. C. Ishiekwene, “Permutation Approach in Obtaining Control Limits and Interpretation of out of Control Signals in Multivariate Control Charts,” International Journal of Statistics and Applications, vol. 6(6), pp. 408-415, 2016 doi: 10.5923/j.statistics.20160606.10