"2"^^ . "2"^^ . . . . . "RIV/49777513:23520/13:43918225!RIV14-MSM-23520___" . . "mesh skinning; action line; musculoskeletal model; interpolation; muscle modelling; deformation"@en . . "23520" . "90216" . "978-989-8565-46-4" . . "In this paper we present an interpolation method that was derived from the muscle deformation algorithm computed on the gradient domain deformation technique. The method uses linear constraints to preserve the local shape of the muscle and the non-linear volume constraints to preserve the volume of the mesh. The Gauss-Newton method with Lagrange multipliers is used as the main computation algorithm and the interpolation approach serves especially to smooth up deformation steps. Thanks to the interpolation of main bones movement positions by several temporally interpositions, the large distances are optimized and the muscles of the musculoskeletal model are deformed in a more realistic way. The method was implemented in C++ language, using VTK framework and was integrated into the human body framework. Despite the fact that the current implementation is not optimised, all muscles tested were processed in a few minutes on commodity hardware, which is much faster in comparison with the traditional FEM approaches."@en . "Musculoskeletal System Modelling"@en . . "2013-02-21+01:00"^^ . . "Barcelona" . "[6BD402BA9680]" . "R" . "6"^^ . . "RIV/49777513:23520/13:43918225" . "SciTePress" . . "Kohout, Josef" . . . "GRAPP 2013" . "Musculoskeletal System Modelling" . "In this paper we present an interpolation method that was derived from the muscle deformation algorithm computed on the gradient domain deformation technique. The method uses linear constraints to preserve the local shape of the muscle and the non-linear volume constraints to preserve the volume of the mesh. The Gauss-Newton method with Lagrange multipliers is used as the main computation algorithm and the interpolation approach serves especially to smooth up deformation steps. Thanks to the interpolation of main bones movement positions by several temporally interpositions, the large distances are optimized and the muscles of the musculoskeletal model are deformed in a more realistic way. The method was implemented in C++ language, using VTK framework and was integrated into the human body framework. Despite the fact that the current implementation is not optimised, all muscles tested were processed in a few minutes on commodity hardware, which is much faster in comparison with the traditional FEM approaches." . . . "Musculoskeletal System Modelling"@en . "Set\u00FAbal" . . . . "H\u00E1jkov\u00E1, Jana" . . "Musculoskeletal System Modelling" . .