Positioning of Quadruped Robot Based on Tightly Coupled LiDAR Vision Inertial Odometer

Quadruped robots, an important class of unmanned aerial vehicles, have broad potential for applications in education, service, industry, military, and other fields. Their independent positioning plays a key role for completing assigned tasks in a complex environment. However, positioning based on gl...

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Bibliographic Details
Published inRemote sensing (Basel, Switzerland) Vol. 14; no. 12; p. 2945
Main Authors Gao, Fangzheng, Tang, Wenjun, Huang, Jiacai, Chen, Haiyang
Format Journal Article
LanguageEnglish
Published Basel MDPI AG 01.06.2022
Subjects
Accuracy
Algorithms
Binocular vision
Blurring
Global navigation satellite system
Jamming
Lasers
Lidar
lidar visual inertial odometer
Localization
Navigation satellites
Normal distribution
Odometers
Optimization
positioning of quadruped robot
Registration
Remote sensing
Robots
Sensors
Task complexity
Three dimensional models
tightly coupled nonlinear optimization
Unmanned aerial vehicles
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Summary:Quadruped robots, an important class of unmanned aerial vehicles, have broad potential for applications in education, service, industry, military, and other fields. Their independent positioning plays a key role for completing assigned tasks in a complex environment. However, positioning based on global navigation satellite systems (GNSS) may result in GNSS jamming and quadruped robots not operating properly in environments sheltered by buildings. In this paper, a tightly coupled LiDAR vision inertial odometer (LVIO) is proposed to address the positioning inaccuracy of quadruped robots, which have poor mileage information obtained though legs and feet structures only. With this optimization method, the point cloud data obtained by 3D LiDAR, the image feature information obtained by binocular vision, and the IMU inertial data are combined to improve the precise indoor and outdoor positioning of a quadruped robot. This method reduces the errors caused by the uniform motion model in laser odometer as well as the image blur caused by rapid movements of the robot, which can lead to error-matching in a dynamic scene; at the same time, it alleviates the impact of drift on inertial measurements. Finally, the quadruped robot in the laboratory is used to build a physical platform for verification. The experimental results show that the designed LVIO effectively realizes the positioning of four groups of robots with high precision and strong robustness, both indoors or outdoors, which verify the feasibility and effectiveness of the proposed method.
ISSN:2072-4292
2072-4292
DOI:10.3390/rs14122945