An Iterative Kalman-Like Algorithm Ignoring Noise and Initial Conditions

Author

Shmaliy, Yuriy S.

Author_Institution

Dept. of Electron., Guanajuato Univ., Salamanca, Mexico

Volume

59

Issue

6

fYear

2011

fDate

6/1/2011 12:00:00 AM

Firstpage

2465

Lastpage

2473

Abstract

We address a p -shift finite impulse response (FIR) unbiased estimator (UE) for linear discrete time-varying filtering (p=0), p-step prediction (p >; 0), and p-lag smoothing (p <; 0) in state space with no requirements for initial conditions and zero mean noise. A solution is found in a batch form and represented in a computationally efficient iterative Kalman-like one. It is shown that the Kalman-like FIR UE is able to outperform the Kalman filter if the noise covariances and initial conditions are not known exactly, noise is not white, and both the system and measurement noise components need to be filtered out. Otherwise, the errors are similar. Extensive numerical studies of the FIR UE are provided in Gaussian and non-Gaussian environments with outliers and temporary uncertainties.

Keywords

FIR filters; Kalman filters; iterative methods; signal denoising; smoothing methods; time-varying filters; FIR unbiased estimator; Kalman-like FIR UE; finite impulse response unbiased estimator; iterative Kalman-like algorithm; linear discrete time-varying filtering; measurement noise components; noise covariances; nonGaussian environments; Finite impulse response filter; Hidden Markov models; Kalman filters; Mathematical model; Noise; Robustness; Signal processing algorithms; Error bound; Kalman-like algorithm; noise power gain; unbiased FIR estimator;

fLanguage

English

Journal_Title

Signal Processing, IEEE Transactions on

Publisher

ieee

ISSN

1053-587X

Type

jour

DOI

10.1109/TSP.2011.2129516

Filename

5734871