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Cluster Computing

Erschienen in:

31.05.2017

Robust and reliable estimation via recursive nonlinear dynamic data reconciliation based on cubature Kalman filter

verfasst von: Min Bian, Jianlin Wang, Weimin Liu, Kepeng Qiu

Erschienen in: Cluster Computing | Ausgabe 4/2017

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Abstract

Since measurements of process variables are subject to measurements errors as well as process variability, data reconciliation is the procedure of optimally adjusting measured date so that the adjusted values obey the conservation laws and constraints. Thus, data reconciliation for dynamic systems is fundamental and important for control, fault detection, and system optimization. Attempts to successfully implement estimators are often hindered by serve process nonlinearities, complicated state constraints, and un-measurable perturbations. As a constrained minimization problem, the dynamic data reconciliation is dynamically carried out to product smoothed estimates with variances from the original data. Many algorithms are proposed to solve such state estimation such as the extended Kalman filter (EKF), the unscented Kalman filter, and the cubature Kalman filter (CKF). In this paper, we investigate the use of CKF algorithm in comparative with the EKF to solve the nonlinear dynamic data reconciliation problem. First we give a broad overview of the recursive nonlinear data dynamic reconciliation (RNDDR) scheme, then present an extension to the CKF algorithm, and finally address the issue of how to solve the constraints in the CKF approach. The CCRNDDR method is proposed by applying the RNDDR in the CKF algorithm to handle nonlinearity and algebraic constraints and bounds. As the sampling idea is incorporated into the RNDDR framework, more accurate estimates can obtained via the recursive nature of the estimation procedure. The performance of the CKF approach is compared with EKF and RNDDR on nonlinear process systems with constraints. The conclusion is that with an error optimization solution of the correction step, the reformulated CKF shows high performance on the selection of nonlinear constrained process systems. Simulation results show the CCRNDDR is an efficient, accurate and stable method for real-time state estimation for nonlinear dynamic processes.

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Shestakov, A.L.: Dynamic error correction method. IEEE Trans Instrum. Meas. 45, 250–255 (1996)CrossRef

Kuehn, D.R., Davidson, H.: Computer control II. Mathematics of control. Chem. Eng. Prog. 6, 44–47 (1961)

Zefang, L., Huajing, F., Lisha, X.: Increasing mapping based hidden Markov model for dynamic process monitoring and diagnosis. Expert Syst. Appl. 41, 744–751 (2014)CrossRef

Crowe, C.M., Campos, Y.A.: Reconciliation of process flow rates by matrix projection. Part 1. Linear case. AIChE J. 29, 881–888 (1983)CrossRef

Kretsovalis, A., Mah, R.S.H.: Effect of redundancy on estimation accuracy in process data reconciliation. Chem. Eng. Sci. 42, 2115–2121 (1987)CrossRef

Crowe, C.M.: Data reconciliation—progress and challenges. J. Process Control 6, 89–98 (1996)CrossRef

Bagajewicz, M.J., Jiang, Q.: Comparison of steady-state and integral dynamic data reconciliation. Comput. Chem. Eng. 24, 2367–2383 (2000)CrossRef

Prakash, J., Huang, B., Shah, S.L.: Recursive constrained state estimation using modified extended Kalman filter. Comput. Chem. Eng. 6, 1–31 (2014)

Vachhani, Pramod, Narasimhan, Shankar, Rengaswamy, Raghunathan: Robust and reliable estimation via unscented recursive nonlinear dynamic data reconciliation. J. Process Control 16, 1075–1086 (2006)CrossRef

10.

Bai, Shuanghua, Thibault, Julies, McLean, David D.: Dynamic data reconciliation: alternative to Kalman filter. J. Process Control 16, 485–498 (2006)CrossRef

11.

Kadu, S.C., Bhushan, M., Gudi, R., Roy, K.: Modified unscented recursive nonlinear dynamic data reconciliation for constrained state estimation. J. Process Control 20, 525–537 (2010)CrossRef

12.

Mandela, R.K., Kuppuraj, V., Rengaswamy, R., Narasimhan, S.: Constrained unscented recursive estimator for nonlinear dynamic systems. J. Process Control 22, 718–728 (2012)CrossRef

13.

WenlingLi, ShihaoSun, YingminJia, JunpingDu: Robust unscented Kalman filter with adaptation of process and measurement noise covariances. Digit. Signal Proc. 48, 93–103 (2016)CrossRefMathSciNet

14.

Wang, Xiaoxu, Liang, Yan, Pan, Quan, Zhao, Chunhui, Yang, Feng: Design and implementation of Gaussian filter for nonlinear system with randomly delayed measurements and correlated noises. Appl. Math. Comput. 232, 1011–1024 (2014)MathSciNet

15.

Julier, S.J., Uhlman, J.K.: Unscented filtering and nonlinear estimation. Proc. IEEE 92, 401–422 (2004)CrossRef

16.

Ienkaran, A., Simon, H.: Cubature Kalman filters. IEEE Trans. Autom. Control 54(6), 1254–1269 (2009)CrossRefMATHMathSciNet

17.

Chitralekha, S.B., Prakash, J., Raghavan, H.: A comparison of simultaneous state and parameter estimation for a continuous fermentor reactor. J. Process Control 20, 934–943 (2010)CrossRef

18.

Arasaratnam, I., Haykin, S., Hurd, T.R.: Cubature Kalman filtering for continuous-discrete systems: theory and simulations. IEEE Trans Signal Process 58(10), 4977–4993 (2010)CrossRefMathSciNet

19.

Gadsden, S.A., AI-Shabi, M., Arasaratnam, I., Habibi, S.R.: Combined cubature Kalman and smooth variable structure filtering: a robust nonlinear estimation strategy. Signal Process. 96, 290–299 (2014)CrossRef

20.

Kolås, S., Foss, B., Schei, T.: Constrained nonlinear state estimation based on the UKF approach. Comput. Chem. Eng. 33, 1368–1401 (2009)CrossRef

21.

Prakash, J., Patwardhan, S.C., Shah, S.L.: Constrained state estimation using ensemble Kalman filter. Ind. Eng. Chem. Res. 49, 2242–2253 (2010)CrossRef

22.

Jia, Bin, Xin, Ming, Cheng, Yang: High-degree cubature Kalman filter. Automatica 49, 510–518 (2013)CrossRefMATHMathSciNet

23.

Liqiang, Zhao, Wang Jianlin, Yu., Tao, Jian Huan, Tangjiang, Liu: Design of adaptive robust square-root cubature Kalman filter with noise statistic estimator. Appl. Math. Comput. 256, 352–367 (2015)CrossRefMATHMathSciNet

24.

Vachhani, P., Narasimhan, S., Rengaswamy, R.: Robust and reliable Estimation via unscented recursive nonlinear dynamic data reconciliation. J. Process Control 16, 1075–1086 (2006)CrossRef

25.

Vachhani, P., Rengaswamy, R., Gangwal, V., Narasimhan, S.: Recursive estimation in constrained nonlinear dynamical systems. AIChE J. 51, 946–959 (2005)CrossRef

26.

Leong, P.H., Arulampalam, S., Lamahewa, T.A., Abhayapala, T.D.: A Gaussian-sum based cubature Kalman filter for bearings-only tracking. IEEE Trans. Aerosp. Elec. Syst 49(2), 1161–1176 (2013)CrossRef

27.

Haseltine, E., Rawlings, J.: Critical evaluation of extended Kalman filtering and moving horizon estimation. Ind. Eng. Chem. Res. 8, 2451–2460 (2005)CrossRef

Titel: Robust and reliable estimation via recursive nonlinear dynamic data reconciliation based on cubature Kalman filter
verfasst von: Min Bian
Jianlin Wang
Weimin Liu
Kepeng Qiu
Publikationsdatum: 31.05.2017
Verlag: Springer US
Erschienen in: Cluster Computing / Ausgabe 4/2017
Print ISSN: 1386-7857
Elektronische ISSN: 1573-7543
DOI: https://doi.org/10.1007/s10586-017-0926-0

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