Shanggang Lin scite author profile

Landing an unmanned aerial vehicle (UAV) autonomously and safely is a challenging task. Although the existing approaches have resolved the problem of precise landing by identifying a specific landing marker using the UAV’s onboard vision system, the vast majority of these works are conducted in either daytime or well-illuminated laboratory environments. In contrast, very few researchers have investigated the possibility of landing in low-illumination conditions by employing various active light sources to lighten the markers. In this paper, a novel vision system design is proposed to tackle UAV landing in outdoor extreme low-illumination environments without the need to apply an active light source to the marker. We use a model-based enhancement scheme to improve the quality and brightness of the onboard captured images, then present a hierarchical-based method consisting of a decision tree with an associated light-weight convolutional neural network (CNN) for coarse-to-fine landing marker localization, where the key information of the marker is extracted and reserved for post-processing, such as pose estimation and landing control. Extensive evaluations have been conducted to demonstrate the robustness, accuracy, and real-time performance of the proposed vision system. Field experiments across a variety of outdoor nighttime scenarios with an average luminance of 5 lx at the marker locations have proven the feasibility and practicability of the system.

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Metric sensing and control of a quadrotor using a homography-based visual inertial fusion method

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et al. 2016

Robotics and Autonomous Systems

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Real-time visual odometry for autonomous MAV navigation using RGB-D camera

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Garratt

Anavatti

et al. 2015

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Real-time 6DoF deck pose estimation and target tracking for landing an UAV in a cluttered shipboard environment using on-board vision

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Garratt

Lambert

2015

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Application of Matlab to the vision-based navigation of UAVs

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Hsiao

Shen

et al. 2010

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Inertial-Aided Metric States and Surface Normal Estimation using a Monocular Camera

Garratt

Lambert

et al. 2017

J Intell Robot Syst

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Shanggang Lin

Monocular vision-based real-time target recognition and tracking for autonomously landing an UAV in a cluttered shipboard environment

Real-Time Monocular Vision System for UAV Autonomous Landing in Outdoor Low-Illumination Environments

Metric sensing and control of a quadrotor using a homography-based visual inertial fusion method

Real-time visual odometry for autonomous MAV navigation using RGB-D camera

Real-time 6DoF deck pose estimation and target tracking for landing an UAV in a cluttered shipboard environment using on-board vision

Application of Matlab to the vision-based navigation of UAVs

Inertial-Aided Metric States and Surface Normal Estimation using a Monocular Camera

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