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Journal of Intelligent Manufacturing

Erschienen in:

29.07.2014

Remaining useful life prediction using prognostic methodology based on logical analysis of data and Kaplan–Meier estimation

verfasst von: Ahmed Ragab, Mohamed-Salah Ouali, Soumaya Yacout, Hany Osman

Erschienen in: Journal of Intelligent Manufacturing | Ausgabe 5/2016

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Abstract

Most of the reported prognostic techniques use a small number of condition indicators and/or use a thresholding strategies in order to predict the remaining useful life (RUL). In this paper, we propose a reliability-based prognostic methodology that uses condition monitoring (CM) data which can deal with any number of condition indicators, without selecting the most significant ones, as many methods propose. Moreover, it does not depend on any thresholding strategies provided by the maintenance experts to separate normal and abnormal values of condition indicators. The proposed prognostic methodology uses both the age and CM data as inputs to estimate the RUL. The key idea behind this methodology is that, it uses Kaplan–Meier as a time-driven estimation technique, and logical analysis of data as an event-driven diagnostic technique to reflect the effect of the operating conditions on the age of the monitored equipment. The performance of the estimated RUL is measured in terms of the difference between the predicted and the actual RUL of the monitored equipment. A comparison between the proposed methodology and one of the common RUL prediction technique; Cox proportional hazard model, is given in this paper. A common dataset in the field of prognostics is employed to evaluate the proposed methodology.

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Alexe, S., Blackstone, E., Hammer, P. L., Ishwaran, H., Lauer, M. S., & Pothier Snader, C. E. (2003). Coronary risk prediction by logical analysis of data. Annals of Operations Research, 119, 15–42.CrossRef

Alexe, G., Alexe, S., Bonates, T. O., & Kogan, A. (2007). Logical analysis of data—the vision of Peter L. Hammer. Annals of Mathematics and Artificial Intelligence, 49, 265–312.CrossRef

Banjevic, D., & Jardine, A. (2007). Remaining useful life in condition based maintenance: Is it useful? In Modelling in industrial maintenance and reliability (p. 7).

Bennane, A., & Yacout, S. (2012). LAD-CBM; new data processing tool for diagnosis and prognosis in condition-based maintenance. Journal of Intelligent Manufacturing, 23, 265–275.CrossRef

Bores, E., Hammer, P. L., Ibaraki, T., Kogan, A., Mayoraz, E., & Muchnik, I. (2000). An implementation of logical analysis of data. IEEE Transactions on Knowledge and Data Engineering, 12, 292–306.CrossRef

Caesarendra, W., Widodo, A., & Yang, B. S. (2010). Application of relevance vector machine and logistic regression for machine degradation assessment. Mechanical Systems and Signal Processing, 24, 1161–1171.CrossRef

Crama, Y., Hammer, P. L., & Ibaraki, T. (1988). Cause-effect relationships and partially defined Boolean functions. Annals of Operations Research, 16, 299–325.CrossRef

Daniel, W. W. (1990). Applied nonparametric statistics (2nd ed.). Boston: PWS-KENT Pub.

Duda, R. O., Hart, P. E., & Stork, D. G. (2001). Pattern classification. A Wiley-Interscience publication. New York: Wiley.

Elsayed, E. A. (2012). Reliability engineering. London: Wiley.

Friedman, J., Hastie, T., & Tibshirani, R. (2001). The elements of statistical learning (Vol. 1). Springer Series in Statistics.

Guo, C., & Ryoo, H. S. (2012). Compact MILP models for optimal and Pareto-optimal LAD patterns. Discrete Applied Mathematics, 160, 2339–2348.

Gwet, K. L. (2011). The practical guide to statistics: Applications with excel, R, and calc. Gaithersburg, MD: Advanced Analytics, LLC.

Hamada, M. (2005). Using degradation data to assess reliability. Quality Engineering, 17, 615–620.CrossRef

Hammer, P. L., Kogan, A., Simeone, B., & Szedmák, S. (2004). Pareto-optimal patterns in logical analysis of data. Discrete Applied Mathematics, 144, 79–102.CrossRef

Hammer, P. L., & Bonates, T. O. (2006). Logical analysis of data—an overview: From combinatorial optimization to medical applications. Annals of Operations Research, 148, 203–225.CrossRef

Heng, A., Tan, A. C. C., Mathew, J., Montgomery, N., Banjevic, D., & Jardine, A. K. S. (2009). Intelligent condition-based prediction of machinery reliability. Mechanical Systems and Signal Processing, 23, 1600–1614.CrossRef

Hosmer, D. W, Jr, & Lemeshow, S. (2011). Applied survival analysis: Regression modeling of time to event data (Vol. 618). New York: Wiley.

Jardine, A., Joseph, T., & Banjevic, D. (1999). Optimizing condition-based maintenance decisions for equipment subject to vibration monitoring. Journal of Quality in Maintenance Engineering, 5, 192– 202.CrossRef

Jardine, A. K. S., Lin, D., & Banjevic, D. (2006). A review on machinery diagnostics and prognostics implementing condition-based maintenance. Mechanical systems and signal processing, 20, 1483– 1510.CrossRef

Kim, H.-E., Tan, A. C., Mathew, J., & Choi, B.-K. (2012). Bearing fault prognosis based on health state probability estimation. Expert Systems with Applications, 39, 5200–5213.

Klein, J., & Moeschberger, M. (1997). Survival analysis: Techniques for censored and truncated data. New York: Spring.CrossRef

Kothamasu, R., Huang, S. H., & VerDuin, W. H. (2006). System health monitoring and prognostics—a review of current paradigms and practices. The International Journal of Advanced Manufacturing Technology, 28, 1012–1024.CrossRef

Kronek, L. P., & Reddy, A. (2008). Logical analysis of survival data: Prognostic survival models by detecting high-degree interactions in right-censored data. Bioinformatics, 24, i248–i253.CrossRef

Le Son, K., Fouladirad, M., Barros, A., Levrat, E., & Iung, B. (2013). Remaining useful life estimation based on stochastic deterioration models: A comparative study. Reliability Engineering and System Safety, 112, 165–175.CrossRef

Liao, H., Zhao, W., & Guo, H. (2006). Predicting remaining useful life of an individual unit using proportional hazards model and logistic regression model (pp. 127–132).

Mortada, M.-A., Yacout, S., & Lakis, A. (2013). Fault diagnosis in power transformers using multi-class logical analysis of data. Journal of Intelligent Manufacturing. doi:10.1007/s10845-013-0750-1.

Mortada, M.-A., Yacout, S., & Lakis, A. (2011). Diagnosis of rotor bearings using logical analysis of data. Journal of Quality in Maintenance Engineering, 17, 371–397.CrossRef

Pintilie, M. (2006). Competing risks: A practical perspective (Vol. 58). New York: Wiley.CrossRef

Ryoo, H. S., & Jang, I. Y. (2009). Milp approach to pattern generation in logical analysis of data. Discrete Applied Mathematics, 157, 749–761.CrossRef

Saha, B., & Goebel, K. (2008). Uncertainty management for diagnostics and prognostics of batteries using Bayesian techniques (pp. 1–8).

Saxena, A., Goebel, K., Simon, D., & Eklund, N. (2008). Damage propagation modeling for aircraft engine run-to-failure simulation (pp. 1–9).

Schwabacher, M., & Goebel, K. (2007). A survey of artificial intelligence for prognostics. Paper presented at the Artificial Intelligence for Prognostics-AAAI Fall Symposium, November 9–11 (pp. 107–114). Arlington, VA.

Tan, A., Heng, A. S. Y., & Mathew, J. (2009). Condition-based prognosis of machine health. In Proceedings of the 13th Asia-Pacific Vibration Conference (pp. 1–10). University of Canterbury.

Tian, Z., Lin, D., & Wu, B. (2012). Condition based maintenance optimization considering multiple objectives. Journal of Intelligent Manufacturing, 23, 333–340.

Tian, Z., Wong, L., & Safaei, N. (2010). A neural network approach for remaining useful life prediction utilizing both failure and suspension histories. Mechanical Systems and Signal Processing, 24, 1542–1555.CrossRef

Vachtsevanos, G. J., Lewis, F. L., Roemer, M., Hess, A., & Wu, B. (2006). Intelligent fault diagnosis and prognosis for engineering systems. London: Wiley.

Wang, W. (2007). A prognosis model for wear prediction based on oil-based monitoring. Journal of the Operational Research Society, 58, 887–893.

Widodo, A., & Yang, B. S. (2007). Support vector machine in machine condition monitoring and fault diagnosis. Mechanical Systems and Signal Processing, 21, 2560–2574.CrossRef

Witten, I. H., Frank, E., & Hall, M. A. (2011). Data mining: Practical machine learning tools and techniques. Los Altos, CA: Morgan Kaufmann.

Titel: Remaining useful life prediction using prognostic methodology based on logical analysis of data and Kaplan–Meier estimation
verfasst von: Ahmed Ragab
Mohamed-Salah Ouali
Soumaya Yacout
Hany Osman
Publikationsdatum: 29.07.2014
Verlag: Springer US
Erschienen in: Journal of Intelligent Manufacturing / Ausgabe 5/2016
Print ISSN: 0956-5515
Elektronische ISSN: 1572-8145
DOI: https://doi.org/10.1007/s10845-014-0926-3

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