Dynamic skin deformation simulation using musculoskeletal model and soft tissue dynamics
Akihiko Murai, Q. Youn Hong, Katsu Yamane, Jessica Hodgins
Computational Visual Media (March 2017)
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Deformation of skin and muscle is essential for bringing an animated character to life. This deformation is difficult to animate in a realistic fashion using traditional techniques because of the subtlety of the skin deformations that must move appropriately for the character design. In this paper, we present an algorithm that generates natural, dynamic, and detailed skin deformation (movement and jiggle) from joint angle data sequences. The algorithm has two steps: identification of parameters for a quasi-static muscle deformation model, and simulation of skin deformation. In the identification step, we identify the model parameters using a musculoskeletal model and a short sequence of skin deformation data captured via a dense marker set. The simulation step first uses the quasi-static muscle deformation model to obtain the quasi-static muscle shape at each frame of the given motion sequence (slow jump). Dynamic skin deformation is then computed by simulating the passive muscle and soft tissue dynamics modeled as a mass–spring–damper system. Having obtained the model parameters, we can simulate dynamic skin deformations for subjects with similar body types from new motion data. We demonstrate our method by creating skin deformations for muscle co-contraction and external impacts from four different behaviors captured as skeletal motion capture data. Experimental results show that the simulated skin deformations are quantitatively and qualitatively similar to measured actual skin deformations.

Akihiko Murai, Q. Youn Hong, Katsu Yamane, Jessica Hodgins (March 2017). Dynamic skin deformation simulation using musculoskeletal model and soft tissue dynamics. Computational Visual Media, 3(1).

@article{Hodgins:2017:DOE,
author={Akihiko Murai, Q. Youn Hong, Katsu Yamane, Jessica Hodgins},
title={Dynamic skin deformation simulation using musculoskeletal model and soft tissue dynamics},
journal={Computational Visual Media},
volume={3},
number={1},
year={March 2017},
}
links={http://rdcu.be/wSqH}