Gyroscope-based video stabilisation with auto-calibration

Ovrén, Hannes; Forssén, Per-Erik

doi:10.1109/icra.2015.7139474

Cited by 29 publications

(20 citation statements)

References 22 publications

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“…Unlike object tracking, feature point tracking is the task of accurately estimating the motion of distinctive key-points. It is a core component in many vision systems [1,27,39,48]. Most feature point tracking methods are derived from the classic Kanade-Lucas-Tomasi (KLT) tracker [34,44].…”

Section: Related Workmentioning

confidence: 99%

Beyond Correlation Filters: Learning Continuous Convolution Operators for Visual Tracking

Danelljan

Robinson

Khan

et al. 2016

Lecture Notes in Computer Science

1,464

1,270

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Abstract. Discriminative Correlation Filters (DCF) have demonstrated excellent performance for visual object tracking. The key to their success is the ability to efficiently exploit available negative data by including all shifted versions of a training sample. However, the underlying DCF formulation is restricted to single-resolution feature maps, significantly limiting its potential. In this paper, we go beyond the conventional DCF framework and introduce a novel formulation for training continuous convolution filters. We employ an implicit interpolation model to pose the learning problem in the continuous spatial domain. Our proposed formulation enables efficient integration of multi-resolution deep feature maps, leading to superior results on three object tracking benchmarks: OTB-2015 (+5.1% in mean OP), Temple-Color (+4.6% in mean OP), and VOT2015 (20% relative reduction in failure rate). Additionally, our approach is capable of sub-pixel localization, crucial for the task of accurate feature point tracking. We also demonstrate the effectiveness of our learning formulation in extensive feature point tracking experiments. Code and supplementary material are available at

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Section: Related Workmentioning

confidence: 99%

Beyond Correlation Filters: Learning Continuous Convolution Operators for Visual Tracking

Danelljan

Robinson

Khan

et al. 2016

Lecture Notes in Computer Science

1,464

1,270

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“…Using tracking instead of feature matching means that landmarks that are detected more than once will be tracked multiple times by the system. The camera-IMU extrinsics, gyroscope bias, and time offset, were given an initial estimate using the Crisp (Ovrén and Forssén 2015) toolbox. Since Crisp does not support accelerometer measurements, we then refined the initial estimate using Kontiki, described in section 5.1, by optimizing over a short part of the full sequence with the accelerometer bias as a parameter to optimize.…”

Section: Real Datamentioning

confidence: 99%

Trajectory representation and landmark projection for continuous-time structure from motion

Ovrén

Forssén

2019

The International Journal of Robotics Research

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This paper revisits the problem of continuous-time structure from motion, and introduces a number of extensions that improve convergence and efficiency. The formulation with a C 2 -continuous spline for the trajectory naturally incorporates inertial measurements, as derivatives of the sought trajectory. We analyse the behaviour of split interpolation on SO(3) and on R 3 , and a joint interpolation on SE (3), and show that the latter implicitly couples the direction of translation and rotation. Such an assumption can make good sense for a camera mounted on a robot arm, but not for hand-held or body-mounted cameras. Our experiments show that split interpolation on R 3 and SO(3) is preferable over SE (3) interpolation in all tested cases. Finally, we investigate the problem of landmark reprojection on rolling shutter cameras, and show that the tested reprojection methods give similar quality, while their computational load varies by a factor of 2. Figure 1. Rendered model estimated on the RC-Car dataset, using split interpolation. Top: model rendered using Meshlab. Bottom: Sample frames from dataset.

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“…3D methods model the camera trajectory in 3D space for stabilization. To stabilize camera motion, various techniques, including Structure from Motion (SfM) [Liu et al 2009], depth information [Liu et al 2012], 3D plane constraints [Zhou et al 2013], projective 3D reconstruction [Buehler et al 2001], light field [Smith et al 2009], and 3D rotation estimation via gyroscope [Bell et al 2014;Karpenko et al 2011;Ovrén and Forssén 2015], have been used. 2.5D approaches use partial information from 3D models, and can handle reconstruction failure cases.…”

Section: Related Workmentioning

confidence: 99%