Resilient Ground Vehicle Autonomous Navigation in GPS-Denied Environments

Kleio Baxevani; Indrajeet Yadav; Yulin Yang; Michael Sebok; Herbert G. Tanner; Guoquan Huang

doi:10.1142/S2737480722500200

Resilient Ground Vehicle Autonomous Navigation in GPS-Denied Environments

Kleio Baxevani
, Indrajeet Yadav
, Yulin Yang
, Michael Sebok
, Herbert G. Tanner
, Guoquan Huang

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Co-design and integration of vehicle navigation and control and state estimation is key for enabling field deployment of mobile robots in GPS-denied cluttered environments, and sensor calibration is critical for successful operation of both subsystems. This paper demonstrates the potential of this co-design approach with field tests of the integration of a reactive receding horizon-based motion planner and controller with an inertial aided multi-sensor calibration scheme. The reported method provides accurate calibration parameters that improve the performance of the state estimator, and enable the motion controller to generate smooth and continuous minimal-jerk trajectories based on local LiDAR data. Numerical simulations in Unity, and real-world experimental results from the field corroborate the claims of efficacy for the reported autonomous navigation computational pipeline.

Original language	English
Article number	2250020
Journal	Guidance, Navigation and Control
Volume	2
Issue number	4
DOIs	https://doi.org/10.1142/S2737480722500200
State	Published - Dec 1 2022
Externally published	Yes

Keywords

Field robots
calibration and identification
motion and path planning

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10.1142/S2737480722500200

Cite this

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title = "Resilient Ground Vehicle Autonomous Navigation in GPS-Denied Environments",

abstract = "Co-design and integration of vehicle navigation and control and state estimation is key for enabling field deployment of mobile robots in GPS-denied cluttered environments, and sensor calibration is critical for successful operation of both subsystems. This paper demonstrates the potential of this co-design approach with field tests of the integration of a reactive receding horizon-based motion planner and controller with an inertial aided multi-sensor calibration scheme. The reported method provides accurate calibration parameters that improve the performance of the state estimator, and enable the motion controller to generate smooth and continuous minimal-jerk trajectories based on local LiDAR data. Numerical simulations in Unity, and real-world experimental results from the field corroborate the claims of efficacy for the reported autonomous navigation computational pipeline.",

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author = "Kleio Baxevani and Indrajeet Yadav and Yulin Yang and Michael Sebok and Tanner, \{Herbert G.\} and Guoquan Huang",

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AU - Baxevani, Kleio

AU - Yadav, Indrajeet

AU - Yang, Yulin

AU - Sebok, Michael

AU - Tanner, Herbert G.

AU - Huang, Guoquan

PY - 2022/12/1

Y1 - 2022/12/1

N2 - Co-design and integration of vehicle navigation and control and state estimation is key for enabling field deployment of mobile robots in GPS-denied cluttered environments, and sensor calibration is critical for successful operation of both subsystems. This paper demonstrates the potential of this co-design approach with field tests of the integration of a reactive receding horizon-based motion planner and controller with an inertial aided multi-sensor calibration scheme. The reported method provides accurate calibration parameters that improve the performance of the state estimator, and enable the motion controller to generate smooth and continuous minimal-jerk trajectories based on local LiDAR data. Numerical simulations in Unity, and real-world experimental results from the field corroborate the claims of efficacy for the reported autonomous navigation computational pipeline.

AB - Co-design and integration of vehicle navigation and control and state estimation is key for enabling field deployment of mobile robots in GPS-denied cluttered environments, and sensor calibration is critical for successful operation of both subsystems. This paper demonstrates the potential of this co-design approach with field tests of the integration of a reactive receding horizon-based motion planner and controller with an inertial aided multi-sensor calibration scheme. The reported method provides accurate calibration parameters that improve the performance of the state estimator, and enable the motion controller to generate smooth and continuous minimal-jerk trajectories based on local LiDAR data. Numerical simulations in Unity, and real-world experimental results from the field corroborate the claims of efficacy for the reported autonomous navigation computational pipeline.

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KW - motion and path planning

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Resilient Ground Vehicle Autonomous Navigation in GPS-Denied Environments

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Keywords

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