Accurate indoor mapping using an autonomous unmanned aerial vehicle (UAV)

07/31/2018

∙

An autonomous indoor aerial vehicle requires reliable simul- taneous localization and mapping (SLAM), accurate flight control, and robust path planning for navigation. This paper presents a system level combination of these existing technologies for 2D navigation. An Unmanned aerial vehicle (UAV) called URSA (Unmanned Recon and Safety Aircraft) that can autonomously flight and mapping indoors environments with an accuracy of 2 cm was developed. Performance in indoor environments was assessed in terms of mapping and navigation precision.

READ FULL TEXT

Accurate indoor mapping using an autonomous unmanned aerial vehicle (UAV)

Indoor Path Planning for an Unmanned Aerial Vehicle via Curriculum Learning

End-to-End UAV Simulation for Visual SLAM and Navigation

Error State Extended Kalman Filter Multi-Sensor Fusion for Unmanned Aerial Vehicle Localization in GPS and Magnetometer Denied Indoor Environments

UAV/UGV Autonomous Cooperation: UAV Assists UGV to Climb a Cliff by Attaching a Tether

View Planning and Navigation Algorithms for Autonomous Bridge Inspection with UAVs

The Blackbird Dataset: A large-scale dataset for UAV perception in aggressive flight

Multi-Task Regression-based Learning for Autonomous Unmanned Aerial Vehicle Flight Control within Unstructured Outdoor Environments

Accurate indoor mapping using an autonomous unmanned aerial vehicle (UAV)

Related Research

Indoor Path Planning for an Unmanned Aerial Vehicle via Curriculum Learning

End-to-End UAV Simulation for Visual SLAM and Navigation

Error State Extended Kalman Filter Multi-Sensor Fusion for Unmanned Aerial Vehicle Localization in GPS and Magnetometer Denied Indoor Environments

UAV/UGV Autonomous Cooperation: UAV Assists UGV to Climb a Cliff by Attaching a Tether

View Planning and Navigation Algorithms for Autonomous Bridge Inspection with UAVs

The Blackbird Dataset: A large-scale dataset for UAV perception in aggressive flight

Multi-Task Regression-based Learning for Autonomous Unmanned Aerial Vehicle Flight Control within Unstructured Outdoor Environments