CONDENSATION—Conditional Density Propagation forVisual Tracking
International Journal of Computer Vision
On sequential Monte Carlo sampling methods for Bayesian filtering
Statistics and Computing
An Introduction to the Kalman Filter
An Introduction to the Kalman Filter
Introduction to Autonomous Mobile Robots
Introduction to Autonomous Mobile Robots
A Real-Time Hybrid Architecture for Biped Humanoids with Active Vision Mechanisms
Journal of Intelligent and Robotic Systems
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In this article the classical self-localization approach is improved by estimating, independently from the robot's pose, the robot's odometric error and the landmarks' poses. This allows using, in addition to fixed landmarks, dynamic landmarks such as temporally local objects (mobile objects) and spatially local objects (view-dependent objects or textures), for estimating the odometric error, and therefore improving the robot's localization. Moreover, the estimation or tracking of the fixed-landmarks' poses allows the robot to accomplish successfully certain tasks, even when having high uncertainty in its localization estimation (e.g. determining the goal position in a soccer environment without directly seeing the goal and with high localization uncertainty). Furthermore, the estimation of the fixed-landmarks' pose allows having global measures of the robot's localization accuracy, by comparing the real map, given by the real (a priori known) position of the fixed-landmarks, with the estimated map, given by the estimated position of these landmarks. Based on this new approach we propose an improved self-localization system for AIBO robots playing in a RoboCup soccer environment, where the odometric error estimation is implemented using Particle Filters, and the robot's and landmarks' poses are estimated using Extended Kalman Filters. Preliminary results of the system's operation are presented.