Localización a largo plazo de vehículos aéreos no tripulados basada en la percepción tridimensional del entorno

Abstract

Unmanned Aerial Vehicles (UAVs) are currently used in countless civil and commercial applications, and the trend is rising. Outdoor obstacle-free operation based on Global Positioning System (GPS) can be generally assumed thanks to the availability of mature commercial products. However, some applications require their use in confined spaces or indoors, where GPS signals are not available. In order to allow for the safe introduction of autonomous aerial robots in GPS-denied areas, there is still a need for reliability in several key technologies to procure a robust operation, such as localization, obstacle avoidance and planning. Existing approaches for autonomous navigation in GPS-denied areas are not robust enough when it comes to aerial robots, or fail in long-term operation. This dissertation handles the localization problem, proposing a methodology suitable for aerial robots moving in a Three Dimensional (3D) environment using a combination of measurements from a variety of on-board sensors. We have focused on fusing three types of sensor data: images and 3D point clouds acquired from stereo or structured light cameras, inertial information from an on-board Inertial Measurement Unit (IMU), and distance measurements to several Ultra Wide-Band (UWB) radio beacons installed in the environment. The overall approach makes use of a 3D map of the environment, for which a mapping method that exploits the synergies between point clouds and radio-based sensing is also presented, in order to be able to use the whole methodology in any given scenario. The main contributions of this dissertation focus on a thoughtful combination of technologies in order to achieve robust, reliable and computationally efficient long-term localization of UAVs in indoor environments. This work has been validated and demonstrated for the past four years in the context of different research projects related to the localization and state estimation of aerial robots in GPS-denied areas. In particular the European Robotics Challenges (EuRoC) project, in which the author is participating in the competition among top research institutions in Europe. Experimental results demonstrate the feasibility of our full approach, both in accuracy and computational efficiency, which is tested through real indoor flights and validated with data from a motion capture system.