I. Wochner, and S. Schmitt. Software, (2022)Related to: Wochner, I., Driess, D., Zimmermann, H., Haeufle, D. F., Toussaint, M., & Schmitt, S. (2020). Optimality principles in human point-to-manifold reaching accounting for muscle dynamics. Frontiers in computational neuroscience, 14, 38. doi: 10.3389/fncom.2020.00038.
DOI: 10.18419/darus-2871
Abstract
An arm model parametrised using generic literature data for the geometry of the skeleton including attachment points for ligaments and muscles. This arm26 model consists of a musculoskeletal model of the arm with two degrees of freedom actuated by six muscles. The model is prepared to run muscle-driven simulation using a simple biological motor control model. The file contains an archive including all relevant data to run the simulation in the simulator demoa. This needs to be installed separately and is available as open source too (get-demoa.com).If you use this model, please cite the related publications together with this dataset.
Related to: Wochner, I., Driess, D., Zimmermann, H., Haeufle, D. F., Toussaint, M., & Schmitt, S. (2020). Optimality principles in human point-to-manifold reaching accounting for muscle dynamics. Frontiers in computational neuroscience, 14, 38. doi: 10.3389/fncom.2020.00038
%0 Generic
%1 wochner2022arm26
%A Wochner, Isabell
%A Schmitt, Syn
%D 2022
%K darus ubs_10002 ubs_20002 ubs_30190 unibibliografie
%R 10.18419/darus-2871
%T arm26: A Human Arm Model
%X An arm model parametrised using generic literature data for the geometry of the skeleton including attachment points for ligaments and muscles. This arm26 model consists of a musculoskeletal model of the arm with two degrees of freedom actuated by six muscles. The model is prepared to run muscle-driven simulation using a simple biological motor control model. The file contains an archive including all relevant data to run the simulation in the simulator demoa. This needs to be installed separately and is available as open source too (get-demoa.com).If you use this model, please cite the related publications together with this dataset.
@misc{wochner2022arm26,
abstract = {An arm model parametrised using generic literature data for the geometry of the skeleton including attachment points for ligaments and muscles. This arm26 model consists of a musculoskeletal model of the arm with two degrees of freedom actuated by six muscles. The model is prepared to run muscle-driven simulation using a simple biological motor control model. The file contains an archive including all relevant data to run the simulation in the simulator demoa. This needs to be installed separately and is available as open source too (get-demoa.com).If you use this model, please cite the related publications together with this dataset. },
added-at = {2022-06-20T19:02:31.000+0200},
affiliation = {Wochner, Isabell/University of Stuttgart, Schmitt, Syn/University of Stuttgart},
author = {Wochner, Isabell and Schmitt, Syn},
biburl = {https://puma.ub.uni-stuttgart.de/bibtex/2feea2759fd4f4c1a41c8b2196b7a0076/unibiblio},
doi = {10.18419/darus-2871},
howpublished = {Software},
interhash = {86018cd405f6e5d1dfcdc04329283895},
intrahash = {feea2759fd4f4c1a41c8b2196b7a0076},
keywords = {darus ubs_10002 ubs_20002 ubs_30190 unibibliografie},
note = {Related to: Wochner, I., Driess, D., Zimmermann, H., Haeufle, D. F., Toussaint, M., & Schmitt, S. (2020). Optimality principles in human point-to-manifold reaching accounting for muscle dynamics. Frontiers in computational neuroscience, 14, 38. doi: 10.3389/fncom.2020.00038},
orcid-numbers = {Wochner, Isabell/0000-0002-2820-5791, Schmitt, Syn/0000-0002-7768-8961},
timestamp = {2022-06-20T17:02:31.000+0200},
title = {arm26: A Human Arm Model},
year = 2022
}
