Adaptive Dipole Model Based Disturbance Compensation in Nonlinear Magnetic Position Systems

The nonlinear magnetic model of an oscillating ferromagnetic object can be used for accurate real-time estimation of its position. This is useful for piston position estimation in a number of automation and performance improvement applications involving hydraulic actuators, pneumatic cylinders, and internal combustion engines. A significant challenge to magnetic field based position estimation comes from disturbances due to unexpected ferromagnetic objects coming close to the sensors. This paper develops a new disturbance estimation method based on modeling the magnetic disturbance as a dipole with unknown location, magnitude, and orientation. A truncated interval unscented Kalman filter is used to estimate all the parameters of this unknown dipole, in addition to estimating piston position from nonlinear magnetic field models. Experimental data from a pneumatic actuator are used to verify the performance of the developed estimator. Experimental results show that the developed estimator is significantly superior to a linear magnetic field model based disturbance estimator. It can reliably estimate piston position and the unknown dipole parameters in the presence of a variety of unknown disturbances.