R. Plankers scite author profile

We develop a framework for 3-D shape and motion recovery of articulated deformable objects. We propose a formalism that incorporates the use of implicit surfaces into earlier robotics approaches that were designed to handle articulated structures. We demonstrate its effectiveness for human body modeling from synchronized video sequences. Our method is both robust and generic. It could easily be applied to other shape and motion recovery problems.

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Articulated soft objects for video-based body modeling

Plankers

Fua

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We develop a framework for 3-D shape and motion recovery of articulated deformable objects. We propose a formalism that incorporates the use of implicit surfaces into earlier robotics approaches that were designed to handle articulated structures. We demonstrate its effectiveness for human body modeling from video sequences. Our method is both robust and generic. It could easily be applied to other shape and motion recovery problems.

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Skeleton-based motion capture for robust reconstruction of human motion

Herda

Fua²,

Plankers³

et al.

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Local and Global Skeleton Fitting Techniques for Optical Motion Capture

Silaghi

Plankers

Boulic

et al. 1998

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Identifying a precise anatomic skeleton is important in order to ensure high quality motion capture. In this paper we discuss two skeleton fitting techniques based on 3D optical marker data. First a local technique is proposed based on relative marker trajectories. Then it is compared to a global optimization of a skeleton model. Various proposals are made to handle the skin deformation problem. Index Terms-skeleton fitting, motion capture, optical markers

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Using skeleton-based tracking to increase the reliability of optical motion capture

Herda

Fua

Plankers

et al. 2001

Human Movement Science

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Optical motion capture provides an impressive ability to replicate gestures. However, even with a highly professional system there are many instances where crucial markers are occluded or when the algorithm confuses the trajectory of one marker with that of another. This requires much editing work on the user's part before the complete animation is ready for use. In this paper, we present an approach to increasing the robustness of a motion capture system by using an anatomical human model. It includes a reasonably precise description of the skeleton's mobility and an approximated envelope. It allows us to accurately predict the 3-D location and visibility of markers, thus significantly increasing the robustness of the marker tracking and assignment, and drastically reducing--or even eliminating--the need for human intervention during the 3-D reconstruction process.

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R. Plankers

Articulated soft objects for multiview shape and motion capture

Articulated soft objects for video-based body modeling

Skeleton-based motion capture for robust reconstruction of human motion

Local and Global Skeleton Fitting Techniques for Optical Motion Capture

Using skeleton-based tracking to increase the reliability of optical motion capture

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