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Abstract
We propose a simple and practical approach for incorporating the effects of muscle inertia, which has been ignored by previous musculoskeletal simulators in both graphics and biomechanics. We approximate the inertia of the muscle by assuming that muscle mass is distributed along the centerline of the muscle. We express the motion of the musculotendons in terms of the motion of the skeletal joints using a chain of Jacobians, so that at the top level, only the reduced degrees of freedom of the skeleton are used to completely drive both bones and musculotendons. Our approach can handle all commonly used musculotendon path types, including those with multiple path points and wrapping surfaces. For muscle paths involving wrapping surfaces, we use neural networks to model the Jacobians, trained using existing wrapping surface libraries, which allows us to effectively handle the Jacobian discontinuities that occur when musculotendon paths collide with wrapping surfaces. We demonstrate support for higher-order time integrators, complex joints, inverse dynamics, Hill-type muscle models, and differentiability. In the limit, as the muscle mass is reduced to zero, our approach gracefully degrades to traditional simulators without support for muscle inertia. Finally, it is possible to mix and match inertial and non-inertial musculotendons, depending on the application.
Original language | English |
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Article number | 272 |
Pages (from-to) | 1-11 |
Number of pages | 11 |
Journal | ACM Transactions on Graphics |
Volume | 41 |
Issue number | 6 |
Early online date | 30 Nov 2022 |
DOIs | |
Publication status | Published - Dec 2022 |
Bibliographical note
This work was sponsored in part by the National Science Foundation (CAREER-1846368) and by Biotechnology and Biological Sciences Research Council (BB/S003762/1).Fingerprint
Dive into the research topics of 'Differentiable simulation of inertial musculotendons'. Together they form a unique fingerprint.Projects
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Active spring muscle model - a new phenomenological model of skeletal muscle mechanics
Yeo, S.-H. (Principal Investigator)
Biotechnology & Biological Sciences Research Council
8/04/19 → 23/12/25
Project: Research Councils