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NOTE: we log the RMSE of orientation and postion which print by ov_msckf. Unit: [degree, meter]

1. Single param comparision

1.1 Mono Version

use_fej MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
false 2.15,0.35 4.11,0.28 3.92,0.34 2.43,0.50 1.61,0.43 3.98,0.22 5.40,0.17 3.10,0.20 2.21,0.14 3.36,0.22 6.42,0.23 3.52,0.28

fig

calib_cam_intrinsics MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
false 1.00,0.30 0.42,0.15 1.75,0.24 0.99,0.22 1.50,0.50 0.67,0.10 0.62,0.13 1.32,0.13 1.48,0.15 1.63,0.14 1.04,0.23 1.13,0.21

fig

calib_cam_extrinsics MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
false 1.18,0.28 0.78,0.17 1.50,0.21 1.74,0.33 1.29,0.40 0.55,0.10 0.93,0.11 1.46,0.15 1.10,0.13 1.09,0.13 1.24,0.28 1.17,0.21

fig

calib_cam_timeoffset MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
false 1.06,0.22 1.01,0.13 1.67,0.18 0.91,0.23 1.49,0.36 0.48,0.12 0.79,0.12 1.55,0.14 0.66,0.15 1.91,0.10 1.39,0.23 1.17,0.18

fig

max_clones MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
11 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
5 1.09,0.43 0.60,0.16 1.04,0.21 1.33,0.21 2.51,0.45 0.62,0.09 0.78,0.15 1.95,0.15 3.61,58.03 2.40,0.12 1.97,0.20 1.63,5.47
10 0.89,0.21 0.51,0.11 2.32,0.23 1.43,0.24 2.38,0.39 0.57,0.11 1.25,0.11 1.24,0.11 0.71,0.21 1.74,0.13 0.99,0.20 1.27,0.18
20 1.05,0.26 0.74,0.18 1.71,0.24 0.64,0.15 1.08,0.42 0.71,0.11 0.57,0.12 1.52,0.24 0.70,0.12 1.56,0.11 1.07,0.21 1.03,0.20
30 0.90,0.23 0.42,0.13 1.64,0.24 0.85,0.12 1.38,0.48 0.45,0.06 0.71,0.13 0.83,0.14 1.01,0.21 2.09,0.08 1.18,0.30 1.04,0.19

fig

max_slam MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
50 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
0 5.35,1188.32 3.27,241.87 3.96,6.34 1.95,4.04 0.54,0.82 0.79,0.15 0.84,0.24 1.45,0.16 1.82,0.21 1.19,0.14 1.33,0.20 2.05,131.14
20 1.14,0.31 0.57,0.16 2.44,0.28 1.04,0.22 1.37,0.43 0.65,0.12 0.93,0.17 1.63,0.13 0.74,0.20 1.07,0.15 2.60,0.26 1.29,0.22
100 1.05,0.20 0.48,0.17 1.67,0.24 1.09,0.18 1.54,0.39 0.42,0.12 0.90,0.10 1.23,0.11 0.71,0.16 1.84,0.11 1.30,0.21 1.11,0.18
200 1.01,0.28 0.57,0.17 1.75,0.20 0.83,0.18 1.05,0.43 0.44,0.11 0.68,0.12 1.04,0.11 0.86,0.18 1.99,0.10 1.13,0.22 1.03,0.19

fig

feat_representation MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
GLOBAL_3D 0.96,0.25 0.65,0.13 1.53,0.26 0.91,0.24 1.57,0.32 0.47,0.11 0.82,0.11 1.68,0.12 0.88,0.15 1.65,0.13 1.34,0.20 1.13,0.18
GLOBAL_FULL_INVERSE_DEPTH 1.03,0.20 0.70,0.11 1.68,0.18 0.89,0.26 1.41,0.40 0.43,0.10 0.87,0.11 1.36,0.14 0.63,0.16 1.49,0.14 1.51,0.23 1.09,0.19
ANCHORED_3D 1.29,0.40 0.66,0.17 1.70,0.23 1.07,0.26 1.82,0.36 1.38,0.12 0.82,0.13 0.80,0.16 0.69,0.15 1.45,0.18 1.13,0.21 1.16,0.22
ANCHORED_FULL_INVERSE_DEPTH 1.17,0.27 1.00,0.20 2.04,0.23 1.31,0.23 1.58,0.47 0.61,0.11 0.73,0.12 1.35,0.13 0.64,0.14 1.76,0.10 1.18,0.21 1.21,0.20
ANCHORED_MSCKF_INVERSE_DEPTH 1.12,0.28 0.66,0.22 1.70,0.24 1.12,0.24 1.97,0.41 0.39,0.10 0.66,0.11 0.95,0.13 0.70,0.14 1.58,0.12 1.03,0.19 1.08,0.20

fig

1.2 Stereo Version

use_fej MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
false 1.84,0.21 2.09,0.24 1.42,0.18 4.40,0.72 4.12,0.60 2.45,0.13 2.89,0.31 1.76,0.08 1.30,0.13 2.19,0.13 7.67,0.30 2.92,0.28

fig

calib_cam_intrinsics MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
false 1.01,0.18 0.58,0.13 0.94,0.19 0.65,0.17 1.31,0.20 1.17,0.07 1.78,0.77 1.31,0.06 0.61,0.06 2.26,0.08 1.34,0.14 1.18,0.19

fig

calib_cam_extrinsics MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
false 1.21,0.15 0.71,0.12 1.43,0.26 1.62,0.25 0.80,0.22 0.86,0.06 59.24,3432.22 2.29,0.08 0.79,0.06 1.89,0.08 1.77,0.13 6.60,312.15

fig

calib_cam_timeoffset MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
true 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
false 1.10,0.16 1.10,0.15 1.26,0.24 1.05,0.20 1.33,0.23 1.07,0.08 0.60,0.38 1.05,0.10 0.67,0.07 2.14,0.07 1.02,0.14 1.13,0.16

fig

max_clones MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
11 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
5 2.01,0.26 1.02,0.13 1.53,0.25 1.79,0.36 2.06,0.36 0.50,0.05 1.68,0.37 1.94,0.07 0.89,0.05 2.46,0.09 1.39,0.17 1.57,0.20
10 1.36,0.16 0.56,0.09 0.64,0.30 1.48,0.21 0.75,0.22 1.04,0.07 0.63,0.23 1.07,0.08 0.64,0.08 2.20,0.07 1.65,0.14 1.09,0.15
20 1.05,0.14 0.69,0.10 1.48,0.28 0.99,0.22 1.53,0.25 1.16,0.06 0.69,0.25 1.18,0.08 0.67,0.08 1.95,0.08 1.91,0.14 1.21,0.15
30 0.96,0.15 0.47,0.12 1.46,0.24 0.81,0.16 1.45,0.24 0.82,0.06 1.01,0.27 1.62,0.08 0.73,0.09 2.98,0.11 2.02,0.16 1.30,0.15

fig

max_slam MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
50 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
0 1.34,0.19 0.64,0.10 2.45,0.20 2.29,0.35 0.74,0.26 0.90,0.06 1.21,0.25 1.47,0.08 0.77,0.07 1.59,0.08 1.53,0.15 1.36,0.16
20 1.25,0.18 0.84,0.10 1.24,0.18 1.33,0.19 2.03,0.38 1.16,0.08 1.39,0.27 1.28,0.10 0.73,0.08 2.37,0.09 1.26,0.15 1.35,0.16
100 0.92,0.21 0.75,0.13 1.61,0.22 1.30,0.23 0.70,0.18 0.83,0.06 0.78,0.26 0.90,0.09 0.88,0.08 2.29,0.10 1.64,0.13 1.15,0.15
200 0.88,0.18 0.64,0.11 1.25,0.25 1.13,0.17 1.20,0.19 1.03,0.06 0.82,0.25 0.93,0.09 0.68,0.09 2.18,0.10 1.64,0.13 1.13,0.15

fig

feat_representation MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 avg
GLOBAL_3D 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
GLOBAL_FULL_INVERSE_DEPTH 1.88,0.37 0.87,0.09 1.32,0.19 0.44,0.09 1.24,0.27 0.57,0.06 1.31,0.27 1.42,0.09 0.87,0.09 2.62,0.10 1.80,0.16 1.30,0.16
ANCHORED_3D 1.03,0.20 0.60,0.11 1.71,0.23 1.06,0.23 1.62,0.27 1.31,0.08 1.22,0.22 1.51,0.07 0.99,0.10 2.74,0.10 0.97,0.15 1.34,0.16
ANCHORED_FULL_INVERSE_DEPTH 1.05,0.17 0.79,0.13 1.35,0.29 0.42,0.16 1.33,0.21 0.99,0.07 0.86,0.27 2.17,0.07 0.87,0.07 2.55,0.09 1.50,0.14 1.26,0.15
ANCHORED_MSCKF_INVERSE_DEPTH 1.06,0.13 0.44,0.10 1.47,0.22 0.88,0.17 1.74,0.25 0.51,0.05 1.03,0.25 0.75,0.10 0.78,0.08 2.49,0.08 1.34,0.15 1.14,0.14

fig

2. special cases comparision

We test several special cases

2.1 Effect from fej, calib, dt, slam

We use default param for: sliding window(11), feature representation(GLOBAL_3D).

case fej intr extr dt slam MH_01 MH_02 MH_03 MH_04 MH_05 V1_01 V1_02 V1_03 V2_01 V2_02 V2_03 average
Naive 0 0 0 0 0 1.45,0.14 4.09,0.55 1.64,0.15 2.65,0.26 1.00,0.22 2.18,0.11 3.76,0.14 1.95,0.06 1.79,0.09 2.97,0.14 1.45,0.25 2.27,0.19
FEJ 1 0 0 0 0 1.07,0.17 0.56,0.08 2.33,0.21 0.85,0.21 0.86,0.24 0.93,0.07 1.10,0.13 0.81,0.08 2.25,0.13 1.30,0.12 1.06,0.24 1.19,0.15
Extrin 0 0 1 0 0 5.17,0.46 2.92,0.40 1.54,0.20 3.61,0.38 0.97,0.25 0.68,0.07 6.45,0.83 1.89,0.06 3.97,0.17 3.63,0.13 1.47,0.19 2.94,0.28
Extrin+Intrin 0 1 1 0 0 5.07,0.54 2.77,0.41 1.84,0.21 2.83,0.39 6.67,0.76 3.19,0.14 29.81,1651.66 2.27,0.06 4.78,0.20 8.12,0.27 2.63,0.20 6.36,150.44
Extrin+Intrin+camdt 0 1 1 1 0 4.15,0.41 0.48,0.16 2.38,0.20 1.86,0.33 4.42,0.54 1.83,0.11 2.65,0.75 3.39,0.07 5.25,0.21 4.61,0.15 3.78,0.19 3.16,0.28
SLAM 0 0 0 0 50 2.23,0.16 1.46,0.46 3.79,0.21 1.86,0.49 1.12,0.33 0.90,0.10 2.75,0.12 3.40,0.16 1.04,0.08 4.20,0.20 6.66,0.27 2.67,0.23
All Open 1 1 1 1 50 0.97,0.15 0.47,0.10 1.02,0.28 0.88,0.17 1.22,0.26 1.02,0.07 1.16,0.26 1.75,0.08 0.73,0.11 2.75,0.09 1.60,0.14 1.23,0.16
fig

3. Conclusion

  1. FEJ gives an significant improvement of precision on both mono and stereo version, while online calibration on intrinsic, extrinsic as well as dt(cam-imu synchronization error) give no obvious improvement, because EuROC provide good calibrations on these information.
  2. Precision improved along with sliding window size inreased, while calculation increased too. There is no obviouse improvement on precision when sliding window size beyond 20. We found the best sliding window size on EUROC are 20(mono), 10(stereo).
  3. Precision improved along with max slam points inreased, while calculation increased too.

Open VINS

Welcome to the Open VINS project! The Open VINS project houses some core computer vision code along with a state-of-the art filter-based visual-inertial estimator. The core filter is an Extended Kalman filter which fuses inertial information with sparse visual feature tracks. These visual feature tracks are fused leveraging the Multi-State Constraint Kalman Filter (MSCKF) sliding window formulation which allows for 3D features to update the state estimate without directly estimating the feature states in the filter. Inspired by graph-based optimization systems, the included filter has modularity allowing for convenient covariance management with a proper type-based state system. Please take a look at the feature list below for full details on what the system supports.

News / Events

  • January 21, 2020 - Our paper has been accepted for presentation in ICRA 2020. We look forward to seeing everybody there! We have also added links to a few videos of the system running on different datasets.
  • October 23, 2019 - OpenVINS placed first in the IROS 2019 FPV Drone Racing VIO Competition . We will be giving a short presentation at the workshop at 12:45pm in Macau on November 8th.
  • October 1, 2019 - We will be presenting at the Visual-Inertial Navigation: Challenges and Applications workshop at IROS 2019. The submitted workshop paper can be found at this link.
  • August 21, 2019 - Open sourced ov_maplab for interfacing OpenVINS with the maplab library.
  • August 15, 2019 - Initial release of OpenVINS repository and documentation website!

Project Features

  • Sliding window visual-inertial MSCKF
  • Modular covariance type system
  • Comprehensive documentation and derivations
  • Extendable visual-inertial simulator
    • On manifold SE(3) b-spline
    • Arbitrary number of cameras
    • Arbitrary sensor rate
    • Automatic feature generation
  • Five different feature representations
    1. Global XYZ
    2. Global inverse depth
    3. Anchored XYZ
    4. Anchored inverse depth
    5. Anchored MSCKF inverse depth
  • Calibration of sensor intrinsics and extrinsics
    • Camera to IMU transform
    • Camera to IMU time offset
    • Camera intrinsics
  • Environmental SLAM feature
    • OpenCV ARUCO tag SLAM features
    • Sparse feature SLAM features
  • Visual tracking support
    • Monocular camera
    • Stereo camera
    • Binocular camera
    • KLT or descriptor based
  • Static IMU initialization (sfm will be open sourced later)
  • Out of the box evaluation on EurocMav and TUM-VI datasets
  • Extensive evaluation suite (ATE, RPE, NEES, RMSE, etc..)

Demo Videos

IMAGE ALT TEXT IMAGE ALT TEXT IMAGE ALT TEXT IMAGE ALT TEXT

IMAGE ALT TEXT IMAGE ALT TEXT IMAGE ALT TEXT

Credit / Licensing

This code was written by the Robot Perception and Navigation Group (RPNG) at the University of Delaware. If you have any issues with the code please open an issue on our github page with relevant implementation details and references. For researchers that have leveraged or compared to this work, please cite the following:

@Conference{Geneva2020ICRA,
  Title      = {OpenVINS: A Research Platform for Visual-Inertial Estimation},
  Author     = {Patrick Geneva and Kevin Eckenhoff and Woosik Lee and Yulin Yang and Guoquan Huang},
  Booktitle  = {Proc. of the IEEE International Conference on Robotics and Automation},
  Year       = {2020},
  Address    = {Paris, France},
  Url        = {\url{https://github.com/rpng/open_vins}}
}

The codebase is licensed under the GNU General Public License v3 (GPL-3).

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