AeroTraj: Trajectory Planning for Fast, and Accurate 3D Reconstruction Using a Drone-based LiDAR

This paper presents AeroTraj, a system that enables fast, accurate, and automated reconstruction of 3D models of large buildings using a drone-mounted LiDAR. LiDAR point clouds can be used directly to assemble 3D models if their positions are accurately determined. AeroTraj uses SLAM for this, but m...

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Veröffentlicht in:	arXiv.org 2024-06
Hauptverfasser:	Ahmad, Fawad, Shin, Christina, Ghosh, Rajrup, D'Ambrosio, John, Chai, Eugene, Sundaresan, Karthik, Govindan, Ramesh
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Sprache:	eng
Schlagworte:	Computer Science - Robotics Computer Science - Systems and Control Drone aircraft Drones Lidar Real time Reconstruction Three dimensional models
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creator	Ahmad, Fawad Shin, Christina Ghosh, Rajrup D'Ambrosio, John Chai, Eugene Sundaresan, Karthik Govindan, Ramesh
description	This paper presents AeroTraj, a system that enables fast, accurate, and automated reconstruction of 3D models of large buildings using a drone-mounted LiDAR. LiDAR point clouds can be used directly to assemble 3D models if their positions are accurately determined. AeroTraj uses SLAM for this, but must ensure complete and accurate reconstruction while minimizing drone battery usage. Doing this requires balancing competing constraints: drone speed, height, and orientation. AeroTraj exploits building geometry in designing an optimal trajectory that incorporates these constraints. Even with an optimal trajectory, SLAM's position error can drift over time, so AeroTraj tracks drift in-flight by offloading computations to the cloud and invokes a re-calibration procedure to minimize error. AeroTraj can reconstruct large structures with centimeter-level accuracy and with an average end-to-end latency below 250 ms, significantly outperforming the state of the art.
doi_str_mv	10.48550/arxiv.2104.08634
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subjects	Computer Science - Robotics Computer Science - Systems and Control Drone aircraft Drones Lidar Real time Reconstruction Three dimensional models
title	AeroTraj: Trajectory Planning for Fast, and Accurate 3D Reconstruction Using a Drone-based LiDAR
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