EgoCap

Rhodin, Helge; Richardt, Christian; Casas, Dan; Insafutdinov, Eldar; Shafiei, Mohammad; Seidel, Hans‐Peter; Schiele, Bernt; Theobalt, Christian

doi:10.1145/2980179.2980235

Cited by 121 publications

(25 citation statements)

References 69 publications

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“…Yonemoto et al propose indirect inference of arm and torso poses from arm-only RGB-D footage [70] and Jiang attempted to reconstruct full-body pose by analyzing the egomotion and observed scene [22], but indirect predictions have low confidence and accuracy. A first approach towards direct full-body motion capture from the egocentric perspective was proposed by Rhodin et al [39]. A 3D kinematic skeleton model is optimized to explain 2D features in each of the views of a stereo fisheye camera mounted on head-extensions similar in structure to a selfie stick.…”

Section: Body-worn Motion Sensorsmentioning

confidence: 99%

“…Our work is the first approach that performs 3D real-time human body pose estimation from a single head-mounted camera. Previous work [39] has demonstrated successful motion capture with a helmetmounted fisheye stereo pair. While their results are promising, their setup has a number of practical disadvantages.…”

Section: Lightweight Hardware Setupmentioning

confidence: 99%

“…Capturing a large amount of annotated 3D pose data is already a mammoth task for outside-in setups and it is even harder for egocentric data. Since manual labeling in 3D space is impractical, [39] proposes to use marker-less multi-view motion capture with externally mounted cameras to get 3D annotations.…”

Section: Synthetic Training Corpusmentioning

confidence: 99%

“…However, these setups are expensive, require tedious pre-calibration, and often require pose optimization over the entire sequence, which prevents real-time performance. Most closely related to our approach is the EgoCap [39] system that is based on two head mounted fisheye cameras. While it alleviates the problem of a limited capture volume, the setup is quite heavy and requires uncomfortable, obtrusive large extension-sticks.…”

Section: Introductionmentioning

confidence: 99%

See 3 more Smart Citations

Mo²Cap² : Real-time Mobile 3D Motion Capture with a Cap-mounted Fisheye Camera

Chatterjee

Zollhöfer

et al. 2019

IEEE Trans. Visual. Comput. Graphics

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130

113

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Fig. 1. Our real-time mobile 3D pose estimation system is based on a single monocular cap-mounted fisheye camera that is attached to a standard baseball cap. The setup is lightweight and enables 3D pose estimation in everyday situations.Abstract-We propose the first real-time system for the egocentric estimation of 3D human body pose in a wide range of unconstrained everyday activities. This setting has a unique set of challenges, such as mobility of the hardware setup, and robustness to long capture sessions with fast recovery from tracking failures. We tackle these challenges based on a novel lightweight setup that converts a standard baseball cap to a device for high-quality pose estimation based on a single cap-mounted fisheye camera. From the captured egocentric live stream, our CNN based 3D pose estimation approach runs at 60 Hz on a consumer-level GPU. In addition to the lightweight hardware setup, our other main contributions are: 1) a large ground truth training corpus of top-down fisheye images and 2) a disentangled 3D pose estimation approach that takes the unique properties of the egocentric viewpoint into account. As shown by our evaluation, we achieve lower 3D joint error as well as better 2D overlay than the existing baselines.

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Section: Body-worn Motion Sensorsmentioning

confidence: 99%

Section: Lightweight Hardware Setupmentioning

confidence: 99%

Section: Synthetic Training Corpusmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Mo²Cap² : Real-time Mobile 3D Motion Capture with a Cap-mounted Fisheye Camera

Chatterjee

Zollhöfer

et al. 2019

IEEE Trans. Visual. Comput. Graphics

Self Cite

130

113

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show abstract

“…Traffic management at road intersection has been proposed in [10] using network fisheye cameras. Pair of fisheye cameras has been used for pose estimation and motion capture in [11], employing a number of 3D Gaussians to generate a probabilistic body model. Gaussian kernels defined in 3D have also been used for scene modeling, in order to make discrete phenomena, like occlusion, continuous and thus, more easily optimizable [12].…”

Section: Introductionmentioning

confidence: 99%

Efficient Implementation of Gaussian and Laplacian Kernels for Feature Extraction from IP Fisheye Cameras

Delibasis

2018

J. Imaging

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Abstract:The Gaussian kernel, its partial derivatives and the Laplacian kernel, applied at different image scales, play a very important role in image processing and in feature extraction from images. Although they have been extensively studied in the case of images acquired by projective cameras, this is not the case for cameras with fisheye lenses. This type of cameras is becoming very popular, since it exhibits a Field of View of 180 degrees. The model of fisheye image formation differs substantially from the simple projective transformation, causing straight lines to be imaged as curves. Thus the traditional kernels used for processing images acquired by projective cameras, are not optimal for fisheye images. This work uses the calibration of the acquiring fisheye camera to define a geodesic metric for distance between pixels in fisheye images and subsequently redefines the Gaussian kernel, its partial derivatives, as well as the Laplacian kernel. Finally, algorithms for applying in the spatial domain these kernels, as well as the Harris corner detector, are proposed, using efficient computational implementations. Comparative results are shown, in terms of correctness of image processing, efficiency of application for multi scale processing, as well as salient point extraction. Thus we conclude that the proposed algorithms allow the efficient application of standard processing and analysis techniques of fisheye images, in the spatial domain, once the calibration of the specific camera is available.

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