Fusion of Visual-Inertial Odometry with LiDAR Relative Localization for Cooperative Guidance of a Micro-Scale Aerial Vehicle
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A novel relative localization approach for cooperative guidance of a micro-scale Unmanned Aerial Vehicle (UAV) fusing Visual-Inertial Odometry (VIO) with Light Detection and Ranging (LiDAR) is proposed in this paper. LiDAR-based localization is accurate and robust to challenging environmental conditions, but 3D LiDARs are relatively heavy and require large UAV platforms. Visual cameras are cheap and lightweight. However, visual-based self-localization methods exhibit lower accuracy and can suffer from significant drift with respect to the global reference frame. We focus on cooperative navigation in a heterogeneous team of a primary LiDAR-equipped UAV and secondary camera-equipped UAV. We propose a novel cooperative approach combining LiDAR relative localization data with VIO output on board the primary UAV to obtain an accurate pose of the secondary UAV. The pose estimate is used to guide the secondary UAV along trajectories defined in the primary UAV reference frame. The experimental evaluation has shown the superior accuracy of our method to the raw VIO output and demonstrated its capability to guide the secondary UAV along desired trajectories while mitigating VIO drift.
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