Abstract

Camera-based navigation within a given three-dimensional map enables heterogeneous robotic systems to share maps and use more abstract environment models like floor plans. This paper builds upon our previous work, and addresses the problem of how to combine 3D distance information from the map and the current visual image from the robot's camera in order to navigate within this map. The underlying assumption is that features which cause depth changes are also likely to create visual gradients. Based on this assumption, the similarity of visual image and depth images that are synthesized from the 3D map can be used to evaluate pose hypothesis. This paper integrates this idea into a Monte Carlo localization approach and additionally presents its application to path following. The presented approach is evaluated on a synthetic datasets that provides perfect knowledge of the ground truth, as well as two real-world datasets acquired by a heterogeneous robotic team: a proof-of-concept dataset in a scattered indoor environment, and a challenging corridor dataset.