Title :
Sensitivity Penalization Based Robust State Estimation for Uncertain Linear Systems
Author_Institution :
Dept. of Autom. & TNList, Tsinghua Univ., Beijing, China
fDate :
4/1/2010 12:00:00 AM
Abstract :
This technical note deals with robust state estimation when parametric uncertainties nonlinearly affect a plant state-space model, based on a simultaneous minimization of nominal estimation errors and their sensitivities. An analytic solution is derived for the optimal estimator which can be recursively realized. This estimator has a form similar to the robust estimator of , and its computational complexity is comparable to the Kalman filter. Under certain conditions, this robust estimator is proved to converge to a stable system, its estimation errors have a bounded covariance matrix, and the estimate is asymptotically unbiased. Numerical simulations show that the obtained estimator has nice estimation performances.
Keywords :
covariance matrices; linear systems; robust control; sensitivity analysis; state estimation; state-space methods; uncertain systems; Kalman filter; bounded covariance matrix; computational complexity; minimization; nominal estimation errors; numerical simulations; optimal estimator; parametric uncertainties; plant state space model; robust estimator; robust state estimation; sensitivity penalization; stable system; uncertain linear systems; Automation; Computational complexity; Covariance matrix; Estimation error; Filters; Linear systems; Numerical simulation; Recursive estimation; Robustness; State estimation; Uncertainty; Recursive state estimation; regularized least-squares; robustness; structured parametric uncertainty;
Journal_Title :
Automatic Control, IEEE Transactions on
DOI :
10.1109/TAC.2010.2041681
