The use of fake algebraic Riccati equations for co-channel demodulation

Author

Einicke, Garry A. ; White, Langford B. ; Bitmead, Robert R.

Author_Institution

Div. of Exploration & Min., Kenmore, Australia

Volume

51

Issue

9

fYear

2003

Firstpage

2288

Lastpage

2293

Abstract

This paper describes a method for nonlinear filtering based on an adaptive observer, which guarantees the local stability of the linearized error system. A fake algebraic Riccati equation is employed in the calculation of the filter gain. The design procedure attempts to produce a stable filter at the expense of optimality. This contrasts with the extended Kalman filter (EKF), which attempts to preserve optimality via its linearization procedure, at the expense of stability. A passivity approach is applied to deduce stability conditions for the filter error system. The performance is compared with an EKF for a co-channel frequency demodulation application.

Keywords

Riccati equations; adaptive filters; circuit stability; demodulation; filtering theory; frequency modulation; nonlinear filters; observers; tracking filters; EKF; FM signal tracking; adaptive nonlinear filter; adaptive observer; co-channel frequency demodulation; extended Kalman filter; fake algebraic Riccati equations; filter error system; filter gain; frequency modulated signal tracking; linearization procedure; linearized error system; local stability; multiple signals tracking; nonlinear filtering method; passivity approach; stability conditions; stable filter design; Covariance matrix; Demodulation; Filtering; Filters; Frequency; Nonlinear equations; Riccati equations; Stability; State estimation; Uncertainty;

fLanguage

English

Journal_Title

Signal Processing, IEEE Transactions on

Publisher

ieee

ISSN

1053-587X

Type

jour

DOI

10.1109/TSP.2003.815376

Filename

1223541