On infinite horizon active fault diagnosis for a class of non-linear non-Gaussian systems

Punčochár, Ivo; Šmandl, Miroslav

doi:10.2478/amcs-2014-0059

Abstract

The paper considers the problem of active fault diagnosis for discrete-time stochastic systems over an infinite time horizon. It is assumed that the switching between a fault-free and finitely many faulty conditions can be modelled by a finite-state Markov chain and the continuous dynamics of the observed system can be described for the fault-free and each faulty condition by non-linear non-Gaussian models with a fully observed continuous state. The design of an optimal active fault detector that generates decisions and inputs improving the quality of detection is formulated as a dynamic optimization problem. As the optimal solution obtained by dynamic programming requires solving the Bellman functional equation, approximate techniques are employed to obtain a suboptimal active fault detector.

References

Andjelkovic, I., Sweetingham, K. and Campbell, S.L. (2008).
Search in Google Scholar
Active fault detection in nonlinear systems using auxiliary signals, Proceedings of the 2008 American Control Conference, Seattle, WA, USA, pp. 2142-2147.
Search in Google Scholar
Ashari, A.E., Nikoukhah, R. and Campbell, S.L. (2012a). Active robust fault detection in closed-loop systems: Quadratic optimization approach, IEEE Transactions on Automatic Control 57(10): 2532-2544.10.1109/TAC.2012.2188430
Search in Google Scholar
Ashari, A.E., Nikoukhah, R. and Campbell, S.L. (2012b). Effects of feedback on active fault detection, Automatica 48(5): 866-872.10.1016/j.automatica.2012.02.020
Search in Google Scholar
Åström, K.J. (1965). Optimal control of Markov processes with incomplete state information, Journal of Mathematical Analysis and Applications 10(1): 174-205.10.1016/0022-247X(65)90154-X
Search in Google Scholar
Atkinson, A.C. and Donev, A.N. (1992). Optimum Experimental Designs, Oxford University Press, New York, NY.
Search in Google Scholar
Bar-Shalom, Y. (1981). Stochastic dynamic programming: Caution and probing, IEEE Transactions on Automatic Control 26(5): 1184-1194.10.1109/TAC.1981.1102793
Search in Google Scholar
Basseville, M. and Nikiforov, I.V. (1993). Detection of Abrupt Changes-Theory and Application, Prentice Hall, Englewood Cliffs, NJ.
Search in Google Scholar
Bertsekas, D.P. (1995). Dynamic Programming and Optimal Control, Volume I, Athena Scientific, Belmont, MA.
Search in Google Scholar
Blackmore, L., Rajamanoharan, S. and Williams, B.C. (2008). Active estimation for jump Markov linear systems, IEEE Transactions on Automatic Control 53(10): 2223-2236.10.1109/TAC.2008.2006100
Search in Google Scholar
Bu§oniu, L., Babuška, R., Schutter, B.D. and Ernst, D. (2010). Reinforcement Learning and Dynamic Programming Using Function Approximators, CRC Press, Boca Raton, FL.
Search in Google Scholar
Campbell, S.L. and Nikoukhah, R. (2004). Auxiliary Signal Design for Failure Detection, Princeton University Press, Princeton, NJ.10.1515/9781400880041
Search in Google Scholar
Denardo, E.V. (2003). Dynamic Programming: Models and Applications, Dover Publications, Mineola, NY.
Search in Google Scholar
Efron, B. and Tibshirani, R.J. (1994). An Introduction to the Bootstrap, Chapman and Hall, New York, NY.10.1201/9780429246593
Search in Google Scholar
Forbes, C., Evans, M., Hastings, N. and Peacock, B. (2011). Statistical Distributions, 4th Edn., John Wiley & Sons, Inc., Hoboken, NJ.
Search in Google Scholar
Garces, F., Becerra, V.M., Kambhampati, C. and Warwick, K. (2003). Strategies for Feedback Linearisation-A Dynamic Neural Network Approach, Springer-Verlag, London.10.1007/978-1-4471-0065-2
Search in Google Scholar
Goodwin, G.C. and Payne, R.L. (1977). Dynamic System Identification: Experiment Design and Data Analysis, Academic Press, New York, NY.
Search in Google Scholar
Isermann, R. (2006). Fault-Diagnosis Systems: An Introduction from Fault Detection to Fault Tolerance, Springer, Berlin.10.1007/3-540-30368-5
Search in Google Scholar
Julier, S.J. and Uhlmann, J.K. (1997). New extension of the Kalman filter to nonlinear systems, Proceedings of the 1997 SPIE Conference on Signal Processing, Sensor Fusion, and Target Recognition, Orlando, FL, USA, pp. 182-193.
Search in Google Scholar
Keresteciŏglu, F. (1993). Change Detection and Input Design in Dynamical Systems, Research Studies Press, Taunton.
Search in Google Scholar
Kiefer, J.C. (1959). Optimum experimental designs, Journal of the Royal Statistical Society (Series B) 21(2): 272-319.10.1111/j.2517-6161.1959.tb00338.x
Search in Google Scholar
Lee, J.M., Kaisare, N.S. and Lee, J.H. (2006). Choice of approximator and design of penalty function for an approximate dynamic programming based control approach, Journal of Process Control 16(2): 135-156.10.1016/j.jprocont.2005.04.010
Search in Google Scholar
Mehra, R.K. (1974). Optimal input signals for parameter estimation in dynamic systems-Survey and new results, IEEE Transactions on Automatic Control 19(6): 753-768.10.1109/TAC.1974.1100701
Search in Google Scholar
Nett, C.N. (1986). Algebraic aspects of linear control system stability, IEEE Transactions on Automatic Control 31(10): 941-949.10.1109/TAC.1986.1104137
Search in Google Scholar
Niemann, H.H. (2006). A setup for active fault diagnosis, IEEE Transactions on Automatic Control 51(9): 1572-1578.10.1109/TAC.2006.878724
Search in Google Scholar
Niemann, H.H. (2012). A model-based approach to fault-tolerant control, International Journal of Applied Mathematics and Computer Science 22(1): 67-86, DOI: 10.2478/v10006-012-0005-x.10.2478/v10006-012-0005-x
Search in Google Scholar
Poulsen, N.K. and Niemann, H. (2008). Active fault diagnosis based on stochastic tests, International Journal of Applied Mathematics and Computer Science 18(4): 487-496, DOI: 10.2478/v10006-008-0043-6.10.2478/v10006-008-0043-6
Search in Google Scholar
Powell, W.B. (2007). Approximate Dynamic Programming: Solving the Curses of Dimensionality, Wiley-Interscience, Hoboken, NJ.10.1002/9780470182963
Search in Google Scholar
Puig, V. (2010). Fault diagnosis and fault tolerant control using set-membership approaches: Application to real case studies, International Journal of Applied Mathematics and Computer Science 20(4): 619-635, DOI: 10.2478/v10006-010-0046-y.10.2478/v10006-010-0046-y
Search in Google Scholar
Puterman, M.L. (2005). Markov Decision Processes-Discrete Stochastic Dynamic Programming, John Wiley & Sons, Hoboken, NJ.
Search in Google Scholar
Scola, H.R., Nikoukhah, R. and Delebecque, F. (2003). Test signal design for failure detection: A linear programming approach, International Journal of Applied Mathematics and Computer Science 13(4): 515-526.
Search in Google Scholar
Scott, J.K., Findeisen, R., Braatz, R.D. and Raimondo, D.M. (2013). Design of active inputs for set-based fault diagnosis, Proceedings of the 2013 American Control Conference, Washington, DC, USA, pp. 3561-3566. ˇS imandl, M., Kr´alovec, J. and S¨oderstr¨om, T. (2006). Advanced point-mass method for nonlinear state estimation, Automatica 42(7): 1133-1145. Šimandl,M. and Punčochář, I. (2009). Active fault detection and control: Unified formulation and optimal design, Automatica 45(9): 2052-2059. Simandl, M., Punčochář, I. and Královec, J. (2005). Rolling horizon for active fault detection, Proceedings of the 44th IEEE Conference on Decision and Control/European Control Conference 2005, Seville, Spain, pp. 3789-3794.
Search in Google Scholar
Širokŷ, J., Šimandl, M., Axehill, D. and Punčochář, I. (2011). An optimization approach to resolve the competing aims of active fault detection and control, Proceedings of the 50th IEEE Conference on Decision and Control/European Control Conference, Orlando, FL, USA, pp. 3712-3717.
Search in Google Scholar
Zhang, X.J. (1989). Auxiliary Signal Design in Fault Detection and Diagnosis, Springer-Verlag, Berlin. 10.1007/BFb0009313
Search in Google Scholar

On infinite horizon active fault diagnosis for a class of non-linear non-Gaussian systems

Abstract

Paradigm

My account