Low-cost INS/GPS with nonlinear filtering methods

Author

Junchuan Zhou ; Edwan, E. ; Knedlik, S. ; Loffeld, O.

Author_Institution

Center for Sensorsystems (ZESS), Univ. of Siegen, Siegen, Germany

fYear

2010

fDate

26-29 July 2010

Firstpage

1

Lastpage

8

Abstract

For land-based navigation, Euler angles are often used in INS/GPS integrated navigation systems. However, the trigonometric operations required in the updates and forming of the rotation matrices for transforming the INS measurements from the body frame to the navigation frame turns the system model to be highly nonlinear. Besides, using low-cost MEMS-based IMUs, the gyroscope bias errors must be correctly estimated and compensated, which makes the nonlinearity problem a critical one. In this contribution, three Kalman filtering methods (i.e., Extended Kalman filter with simplified system model, Extended Kalman filter with linearized system model and Unscented Kalman filter with nonlinear system model) are utilized in INS/GPS tightly-coupled integration. Simulations and field experiments are conducted. Numerical results are compared in terms of both estimation accuracy and processing time.

Keywords

Global Positioning System; Kalman filters; gyroscopes; inertial navigation; nonlinear filters; Euler angle; INS measurement; INS/GPS integrated navigation system; Kalman filtering; body frame; extended Kalman filter; gyroscope bias error; land-based navigation; low-cost MEMS-based IMU; navigation frame; nonlinear filtering; nonlinear system model; rotation matrix; trigonometric operation; unscented Kalman filter; Earth; Equations; Global Positioning System; Kalman filters; Mathematical model; Receivers; Euler angles; INS/GPS; nonlinear filtering;

fLanguage

English

Publisher

ieee

Conference_Titel

Information Fusion (FUSION), 2010 13th Conference on

Conference_Location

Edinburgh

Print_ISBN

978-0-9824438-1-1

Type

conf

DOI

10.1109/ICIF.2010.5712023

Filename

5712023