Title :
Unscented particle filter for tracking a magnetic dipole target
Author_Institution :
Defence R&D Canada Atlantic, Dartmouth, NS
Abstract :
In this paper we present a recursive Bayesian solution to the problem of joint tracking and classification of a target modeled at a distance by an equivalent magnetic dipole. Tracking/classification of a magnetic dipole from noisy magnetic field measurements involves the modeling of a non-linear non-Gaussian system. This system allows for complications due to multiple directions of arrival and target maneuver. The determination of target position, velocity and magnetic moment is formulated as an optimal stochastic estimation problem, which could be solved using a sequential Monte Carlo based approach known as the particle filter. In addition to the conventional particle filter, the proposed tracking and classification algorithm uses the unscented Kalman filter (UKF) to generate the transition prior as the proposal distribution
Keywords :
Bayes methods; Monte Carlo methods; geophysical signal processing; magnetic field measurement; oceanographic techniques; particle filtering (numerical methods); recursive estimation; stochastic processes; target tracking; magnetic dipole target tracking; noisy magnetic field measurements; nonlinear nonGaussian system; optimal stochastic estimation problem; recursive Bayesian solution; sequential Monte Carlo based approach; target classification; target magnetic moment; target position determination; target velocity; unscented Kalman filter; unscented particle filter; Bayesian methods; Magnetic field measurement; Magnetic moments; Magnetic noise; Magnetic separation; Monte Carlo methods; Particle filters; Particle tracking; Stochastic processes; Target tracking;
Conference_Titel :
OCEANS, 2005. Proceedings of MTS/IEEE
Conference_Location :
Washington, DC
Print_ISBN :
0-933957-34-3
DOI :
10.1109/OCEANS.2005.1639993
