Authors: Hong Son Hoang, Remy Baraille

Abstract:

This paper addresses the problem of how one can improve the performance of a non-optimal filter. First the theoretical question on dynamical representation for a given time correlated random process is studied. It will be demonstrated that for a wide class of random processes, having a canonical form, there exists a dynamical system equivalent in the sense that its output has the same covariance function. It is shown that the dynamical approach is more effective for simulating and estimating a Markov and non- Markovian random processes, computationally is less demanding, especially with increasing of the dimension of simulated processes. Numerical examples and estimation problems in low dimensional systems are given to illustrate the advantages of the approach. A very useful application of the proposed approach is shown for the problem of state estimation in very high dimensional systems. Here a modified filter for data assimilation in an oceanic numerical model is presented which is proved to be very efficient due to introducing a simple Markovian structure for the output prediction error process and adaptive tuning some parameters of the Markov equation.

Keywords: Statistical simulation, canonical form, dynamical system, Markov and non-Markovian processes, data assimilation.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1080183

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References:

[1] Bryson A.E. and Henrikson L.J. (1968) Estimation Using Sampled Data Containing Sequentially Correlated Noise. Journal of Spacecraft, Vol. 5, No. 6, pp. 662-665.
[2] T. Kailath (1968) An Innovations Approach to Least-Squares Estimation, Pt. I: Linear Filtering in Additive Noise, IEEE Trans. Autom. Contr., 13(6), pp. 646-655.
[3] Hoang H.S. and Baraille R. (2011) Approximation Approach to Linear Filtering Problem with Correlated Noise. Engineering and Technology, 59, pp. 298-305.
[4] Hoang H.S. and Baraille R. (2012) On Gain Initialization and Optimization of Reduced-Order Adaptive Filter. Journal IAENG IJAM, 42:1, pp. 19-33.
[5] Lo`eve, M. (1978) Probability theory. Vol. II, 4th ed. Graduate Texts in Mathematics. 46. Springer-Verlag
[6] Nguyen T.L. and Hoang H.S. (1982) On one model of non-Markovian random process and its application to optimal estimation theory. Automat. Remote Contr., 43 (1982), 8 (1), pp. 1021-1032.
[7] Pugachev V.S. and Sinitsyn I.N. (1987). Stochastic systems : theory and applications, John Wiley and Sons.
[8] Golub G.H. and van Loan C.F. (1996). Matrix Computations, Cambridge University Press.