2020
DOI: 10.1109/tim.2019.2931526
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LiDAR-Camera Calibration Under Arbitrary Configurations: Observability and Methods

Abstract: LiDAR-camera calibration is a precondition for many heterogeneous systems that fuse data from LiDAR and camera. However, the constraint from common field of view and the requirement for strict time synchronization make the calibration a challenging problem. In this paper, we propose a novel LiDAR-camera calibration method aiming to eliminate these two constraints. Specifically, we capture a scan of 3D LiDAR when both the environment and the sensors are stationary, then move the camera to reconstruct the 3D env… Show more

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Cited by 54 publications
(23 citation statements)
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“…Fig. 15 shows the horizontal dimensions w both with and without using HDDM+ estimated according to (7). In particular, w without HDDM+ has been estimated using n OLS = 13 -n OLS ≈ (t point−cloud t f ire ) + 1 -, whereas w with HDDM+ has been estimated using n OLS = 37 -n OLS ≈ (3⋅t point−cloud t f ire )+1).…”
Section: Spots Time Arrangementmentioning
confidence: 99%
See 1 more Smart Citation
“…Fig. 15 shows the horizontal dimensions w both with and without using HDDM+ estimated according to (7). In particular, w without HDDM+ has been estimated using n OLS = 13 -n OLS ≈ (t point−cloud t f ire ) + 1 -, whereas w with HDDM+ has been estimated using n OLS = 37 -n OLS ≈ (3⋅t point−cloud t f ire )+1).…”
Section: Spots Time Arrangementmentioning
confidence: 99%
“…Finally, Fig. 16 shows vertical dimensions h as a function of the distance d calculated as described in (7). Note that the manufacturer makes no distinction between the vertical and horizontal dimensions of the spot (see (8)), thus it is not possible to compare the obtained results with the nominal ones.…”
Section: Spots Time Arrangementmentioning
confidence: 99%
“…Thus motivated, this paper is a preliminary study as to whether, and under which conditions, an extended approach based on a set of unordered coplanar chessboards might, in principle, simulate an (infeasibly large) single chessboard, to effectively accommodate longer focusing distances or wider fields of view. Multiple (non-coplanar) or 3D chessboards have already been exploited for camera-to-camera, camera-to-range sensor or multiple depth camera automatic calibration (Geiger et al, 2012;Fuersattel et al, 2017;Yin et al, 2018;Fu et al, 2019;Liu et al 2019). Yet, to the best of our knowledge, the particular use of multiple coplanar chessboards for camera calibration has not been investigated.…”
Section: Introductionmentioning
confidence: 99%
“…Multiple sensors are increasingly being deployed in systems, and the sensors are often There are some existing extrinsic calibration methods available for different types of sensors. For instance, extrinsic calibration algorithms are presented for cameras in [38,39], for a combination of lidar and camera in [40][41][42], and for a combination of laser scanner and camera in [43][44][45][46]. We consider automotive radar sensors in this work.…”
Section: Introductionmentioning
confidence: 99%
“…Some existing calibration methods have been proposed for different sensors; for cameras in [38,39], for lidar and camera in [40][41][42], for laser scanner and camera in [43][44][45][46], for radar and camera in [63][64][65], and for radar, lidar, and camera in [66,67].…”
Section: Introductionmentioning
confidence: 99%