Abstract
Accurate positioning and mapping are significant for autonomous systems with navigation requirements. In this paper, a coarse-to-fine loosely-coupled (LC) LiDAR-inertial odometry (LC-LIO) that could explore the complementariness of LiDAR and inertial measurement unit (IMU) was proposed for the real-time and accurate pose estimation of a ground vehicle in urban environments. Different from the existing tightly-coupled (TC) LiDAR-inertial fusion schemes which directly use all the considered ranges and inertial measurements to optimize the vehicle pose, the method proposed in this paper performs loosely-couped integrated optimization with the high-frequency motion prediction, which was produced by IMU integration based on optimized results, employed as the initial guess of LiDAR odometry to approach the optimality of LiDAR scan-to-map registration. As one of the prominent contributions, thorough studies were conducted on the performance upper bound of the TC LiDAR-inertial fusion schemes and LC ones, respectively. Furthermore, the experimental verification was performed on the proposition that the proposed pipeline can fully relax the potential of the LiDAR measurements (centimeter-level ranging accuracy) in a coarse-to-fine way without being disturbed by the unexpected IMU bias. Moreover, an adaptive covariance estimation method employed during LC optimization was proposed to explain the uncertainty of LiDAR scan-to-map registration in dynamic scenarios. Furthermore, the effectiveness of the proposed system was validated on challenging real-world datasets. Meanwhile, the process that the proposed pipelines realized the coarse-to-fine LiDAR scan-to-map registration was presented in detail. Comparing with the existing state-of-the-art TC-LIO, the focus of this study would be placed on that the proposed LC-LIO work could achieve similar or better accuracy with a reduced computational expense.
Highlights
Positioning and mapping are undoubtedly essential modules for autonomous tasks, such as autonomous driving and robotic service, in unknown or partially known environments
The LC-LIOFC outperforms LiLi-OM at most turns on the ground that it can register each LiDAR
The LiDAR scan-to-map map registration, is the fine process, can produce a globally and registration, which which is the fine process, can produce a globally consistentconsistent map and map conduct conduct a precision motion estimation with the timely and high-frequency initial guess a precision motion estimation with the timely and high-frequency initial guess provided provided by the LC integrated inertial measurement unit (IMU) based on factor graph optimization as the coarse process
Summary
Positioning and mapping are undoubtedly essential modules for autonomous tasks, such as autonomous driving and robotic service, in unknown or partially known environments. It is well known that the Global Navigation Satellite System (GNSS) could provide satisfactory performance in open-sky areas. Due to the reflection caused by static skyscrapers and dynamic tall objects such as double-decker buses, reflected signals from the same satellite could be received and the notorious non-light-of-sight (NLOS). Receptions occur [1], which is the major difficulty significantly degrading the positioning accuracy and preventing GNSS from utilization in intelligent transportation systems under urban canyons [2]. The major principle of LiDAR-based positioning and mapping is to track the motions obtained by registrations between consecutive frames of point clouds [3]. The LiDAR standalone-based odometry is sensitive to motion
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