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Abstract

When a camera rotates rapidly or shakes severely, a conventional KLT (Kanade–Lucas–Tomasi) feature tracker becomes vulnerable to large inter-image appearance changes. Tracking fails in the KLT optimization step, mainly due to an inadequate initial condition equal to final image warping in the previous frame. In this paper, we present a gyro-aided feature tracking method that remains robust under fast camera–ego rotation conditions. The knowledge of the camera’s inter-frame rotation, obtained from gyroscopes, provides an improved initial warping condition, which is more likely within the convergence region of the original KLT. Moreover, the use of an eight-degree-of-freedom affine photometric warping model enables the KLT to cope with camera rolling and illumination change in an outdoor setting. For automatic incorporation of sensor measurements, we also propose a novel camera/gyro auto-calibration method which can be applied in an in-situ or on-the-fly fashion. Only a set of feature tracks of natural landmarks is needed in order to simultaneously recover intrinsic and extrinsic parameters for both sensors. We provide a simulation evaluation for our auto-calibration method and demonstrate enhanced tracking performance for real scenes with aid from low-cost microelectromechanical system gyroscopes. To alleviate the heavy computational burden required for high-order warping, our publicly available GPU implementation is discussed for tracker parallelization.

Keywords

Auto-calibration GPU parallel programming KLT feature tracking visual/inertial sensor fusion

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References

Analog Devices (2010) ADXRS-623 ±150°/sec MEMS Yaw Rate Gyroscope (Data Sheet).

Arun

Huang

Bolstein

(1987) Least-squares fitting of two 3-D point sets. IEEE Trans Pattern Anal Machine Intell 9: 698–700.

Baker

Matthews

(2004) Lucas–Kanade 20 years on: A unifying framework. Int J Comput Vision 56: 221–255.

Bleser

Wohlleber

Becker

Stricker

(2006) Fast and stable tracking for AR fusing video and inertial sensor data. In International Conference in Central Europe on Computer Graphics, Visualization and Computer Vision (WSCG), Plzen, Czech Republic, pp. 109–115.

Bouguet

(2000) Pyramidal Implementation of the Lucas Kanade Feature Tracker: Description of the Algorithm. Technical Report, Intel Corporation, Microprocessor Research Labs, OpenCV Documents.

Chandaria

Thomas

Bartczak

Koeser

Koch

Becker

. (2007) Realtime camera tracking in the MATRIS project. SMPTE Motion Imaging J 116: 266–271.

Corke

Lobo

Dias

(2007) An introduction to inertial and visual sensing. Int J Robotics Res 26: 519–535.

Davison

Reid

Molton

Stasse

(2007) MonoSLAM: Real-time single camera SLAM. IEEE Trans Pattern Recognition Machine Intell 29: 1052–1067.

El-Sheimy

Hou

Niu

(2008) Analysis and modeling of inertial sensors using Allan variance. IEEE Trans Instrumentation Meas 57: 140–149.

10.

Golub

Loan

CFV

(1996) Matrix Computations, 3rd edn. Baltimore, MD: The Johns Hopkins University Press.

11.

Gray

Veth

(2009) Deeply-integrated feature tracking for embedded navigation. In ION International Technical Meeting Program, Anaheim, CA.

12.

Hartley

(1997) Self-calibration of stationary cameras. Int J Comput Vision 22: 5–23.

13.

Hartley

Zisserman

(2004) Multiple View Geometry in Computer Vision, 2nd edn. Cambridge: Cambridge University Press.

14.

Hedborg

Skoglund

Felsberg

(2007) KLT tracking implementation on the GPU. In Proceedings SSBA 2007, Linkoping, Sweden.

15.

Hol

Schön

Gustafsson

(2010) Modeling and calibration of inertial and vision sensors. Int J Robotics Res 29: 231–244.

16.

Hol

Schön

Luinge

Slycke

Gustafsson

(2007) Robust real-time tracking by fusing measurements from inertial and vision sensors. J Real-Time Image Process 2: 149–160.

17.

Hwangbo

Kanade

(2008) Factorization-based calibration method for mems inertial measurement unit. In Proceedings IEEE International Conference on Robotics and Automation, San Hose, CA.

18.

Hwangbo

Kim

J-S

Kanade

(2009) Inertial-aided klt feature tracking for a moving camera. In IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS’09), pp. 1909–1916.

19.

Jin

Favaro

Soatto

(2001) Real-time feature tracking and outlier rejection with changes in illumination. In International Conference on Computer Vision, pp. 684–689.

20.

Kelly

Sukhatme

(2008) Fast relative pose calibration for visual and inertial sensors. In 11th International Symposium Experimental Robotics (ISER’08).

21.

Kim

J-S

Hwangbo

Kanade

(2009) Realtime affine-photometric KLT feature tracker on GPU in CUDA framework. In The Fifth IEEE Workshop on Embedded Computer Vision in ICCV 2009, pp. 1306–1311.

22.

Lang

Pinz

(2005) Calibration of hybrid vision / inertial tracking system. In Proceedings 2nd Workshop on Integration of Vision and Inertial Sensors (INERVIS’05).

23.

Lobo

Dias

(2003) Vision and inertial sensor cooperation using gravity as a vertical reference. IEEE Trans Pattern Recognition Machine Intell 25: 1597–1608.

24.

Lobo

Dias

(2007) Relative pose calibration between visual and inertial sensors. Int J Robotics Res 26: 561–575.

25.

Lucas

Kanade

(1981) An iterative image registration technique with an application to stereo vision. In Proceedings of the 7th International Joint Conference on Artificial Intelligence, Vancouver, Canada, pp. 674–679.

26.

Makadia

Daniilidis

(2005) Correspondenceless ego-motion estimation using an IMU. In Proceedings IEEE International Conference on Robotics and Automation, pp. 3534–3539.

27.

Mirzaei

Roumeliotis

(2008) A Kalman filter-based algorithm for IMU-camera calibration: Observability analysis and performance evaluation. IEEE Trans Robotics 24: 1143–1156.

28.

Ohmer

Redding

(2008) GPU-accelerated KLT tracking with monte-carlo-based feature reselection. In Computing: Techniques and Applications, 2008. DICTA ’08. Digital Image, pp. 234–241.

29.

Sepp

Fuchs

(2010) DLR CalLab and CalDe–The DLR Camera Calibration Toolbox. Available at: http://www.robotic.dlr.de/callab/.

30.

Shi

Tomasi

(1994) Good features to track. In IEEE Conference on Computer Vision and Pattern Recognition (CVPR’94), Seattle, WA.

31.

Sinha

Frahm

J-M

Pollefeys

Genc

(2007) Feature tracking and matching in video using programmable graphics hardware. In Machine Vision and Applications.

32.

Yokokohji

Sugawara

Yoshikawa

(2000) Accurate image overlay on video see-through HMDs using vision and accelerometers. In Proceedings IEEE Virtual Reality.

33.

You

Neumann

Azuma

(1999) Hybrid inertial and vision tracking for augmented reality registration. In Proceedings IEEE Virtual Reality.

34.

Zach

Gallup

Frahm

J-M

(2008) Fast gain-adaptive KLT tracking on the gpu. In IEEE Computer Society Conference on Computer Vision and Pattern Recognition Workshops, 2008. CVPR Workshops 2008, pp. 1–7.

35.

Zhang

Chockalingam

Kumar

Burt

Lakshmikumar

(2008) Qualitative assessment of video stabilization and mosaicking systems. In IEEE Workshop on Applications of Computer Vision (WACV 2008), pp. 1–6.

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Gyro-aided feature tracking for a moving camera: fusion,auto-calibration and GPU implementation

Abstract

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