Fast and agile vision-based flight with teleoperation and collision avoidance on a multirotor

A. E. Spitzer, X. Yang, J. W. Yao, A. Dhawale, K. Goel, M. Dabhi, M. Collins, C. Boirum, and N. Michael

Conference Paper, Proceedings of International Symposium on Experimental Robotics (ISER '18), pp. 524 - 535, November, 2018

Abstract

We present a multirotor architecture capable of aggressive autonomous flight and collision-free teleoperation in unstructured, GPS-denied environments. The proposed system enables aggressive and safe autonomous flight around clutter by integrating recent advancements in visual-inertial state estimation and teleoperation. Our teleoperation framework maps user inputs onto smooth and dynamically feasible motion primitives. Collision-free trajectories are ensured by querying a locally consistent map that is incrementally constructed from forward-facing depth observations. Our system enables a non-expert operator to safely navigate a multirotor around obstacles at speeds of 10 m/s. We achieve autonomous flights at speeds exceeding 12 m/s and accelerations exceeding 12 m/s\(^2\) in a series of outdoor field experiments that validate our approach.

BibTeX

@conference{Spitzer-2018-120094,
author = {A. E. Spitzer and X. Yang and J. W. Yao and A. Dhawale and K. Goel and M. Dabhi and M. Collins and C. Boirum and N. Michael},
title = {Fast and agile vision-based flight with teleoperation and collision avoidance on a multirotor},
booktitle = {Proceedings of International Symposium on Experimental Robotics (ISER '18)},
year = {2018},
month = {November},
pages = {524 - 535},
}

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