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    Human Articular Movement Algorithm to Simulate Muscle Contraction and Embedded Tissue Deformation

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    Date
    2019
    Author
    Atsumi, Noritoshi
    Kato, Daichi
    Hirabayashi, Satoko
    Nakahira, Yuko
    Iwamoto, Masami
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    Abstract
    The visualization of human articular movements associated with internal deformation is critical for many fields including biome- chanics. In this work, we present a novel algorithm to describe realistic articular movement in a human model, which effectiv- elly combines free-form deformation and simple constrained de- formation. The algorithm provides the articular movement with contractions/extensions in muscles followed by the deformations of embedded tissues, such as blood vessels, lymphatics, and nerves, treating the bones as a rigid body. An arm bending simulation of a human model using the algorithm was performed. The proposed algorithm has the potential for development as a hybrid method that combines multi-physical simulations and geometric modeling. the continuous articular movement associated with the deforma- tion of each part is difficult. In particular, the shapes of embed- ded tissues in human limbs, such as blood vessels, lymphatics, and nerves, change due to muscle deformations during skeletal mo- tions. Simulating human articular movement considering such in- ner structures could provide important knowledge for biomechani- cal applications. Our final goal is to provide a plausible virtual hu- man model to represent multi-physical properties by integrating geometric modeling and physical simulation. Here, we propose an algorithm to visually represent human articular movement, com- bining free-form deformation (FFD) [Sederberg and Parry 1986] and simple constrained deformation (Scodef) [Borrel and Rappoport 1994] effectively. One of the contributions of this study is to provide the methodical idea on the representation of muscle-driven deforma- tion of internal tissues that occurs in actual body.
    BibTeX
    @inproceedings {10.1145:3309486.3339892,
    booktitle = {Eurographics/ ACM SIGGRAPH Symposium on Computer Animation},
    editor = {Batty, Christopher and Huang, Jin},
    title = {{Human Articular Movement Algorithm to Simulate Muscle Contraction and Embedded Tissue Deformation}},
    author = {Atsumi, Noritoshi and Kato, Daichi and Hirabayashi, Satoko and Nakahira, Yuko and Iwamoto, Masami},
    year = {2019},
    publisher = {ACM},
    ISSN = {1727-5288},
    ISBN = {978-1-4503-6677-9},
    DOI = {10.1145/3309486.3339892}
    }
    URI
    https://doi.org/10.1145/3309486.3339892
    https://diglib.eg.org:443/handle/10.1145/3309486-3339892
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    Eurographics Association copyright © 2013 - 2022 
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    Theme by @mire NV
    System hosted at  Graz University of Technology.
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