Abstract

Mobile robots rely on the ability to sense the geometry of their local environment in order to avoid obstacles or to explore the surroundings. For this task, dedicated proximity sensors such as laser range finders or sonars are typically employed. Cameras are a cheap and lightweight alternative to such sensors, but do not directly offer proximity information. In this paper, we present a novel approach to learning the relationship between range measurements and visual features extracted from a single monocular camera image. As the learning engine, we apply Gaussian processes, a non-parametric learning technique that not only yields the most likely range prediction corresponding to a certain visual input but also the predictive uncertainty. This information, in turn, can be utilized in an extended grid-based mapping scheme to more accurately update the map. In practical experiments carried out in different environments with a mobile robot equipped with an omnidirectional camera system, we demonstrate that our system is able to produce proximity estimates with an accuracy comparable to that of dedicated sensors such as sonars or infrared range finders.