Structure preserving optimal control of finger movements

Maas R, Leyendecker S, Siebert T (2011)

Publication Language: English

Publication Type: Conference contribution, Conference Contribution

Publication year: 2011

Pages Range: DVD, 16 Seiten

Conference Proceedings Title: Proceedings of the Euromech Colloquium 511 on Biomechanics of Human Motion, DVD, 16 pages

Event location: Ponta Delgada, Azores

Abstract

A common tool to solve dynamical problems, in particular in biomechanic in-

vestigations, is MATLAB/Simulink. Many integration methods, as used for example in MAT-

LAB/Simulink, rely on standard discretisations of the continuous equations of motion. These

methods often lead to time stepping schemes, that show numerical dissipation in energy and

momentum.

In contrast to that, we use a discrete variational principle to derive a time-stepping scheme.

This method yields discrete analogues to the Euler- Lagrange equations and Noether’s theorem,

which ensures that the structure of the underlying continuous dynamical system is preserved.

Using this method, the simulation results are symplectic momentum consistent and exhibit a

good energy behaviour.

We implement a typical nonlinear Hill-type muscle model in the structure preserving simulation

framework and investigate the differences to standard simulation of muscle actuated movements

with MATLAB/Simulink, especially concerning the correct representation of energy and angu-

lar momentum. A numerical example shows that the MATLAB/Simulink integrators artificially

loose or gain energy and angular momentum, whereas all results of the symplectic momentum

method are structure preserving.

With this structure preserving simulation framework including actuation by muscle models, we

investigate the trajectory of fingers during grasping movements. Since human movements are

controlled by the central nervous system (CNS), we formulate finger movements as optimal con-

trol problems for constrained forced motion with a physiologically motivated objective function

as described in [1]. For the solution of the optimal control problem, we use DMOCC (Dis-

crete Mechanics and Optimal Control for Constrained Systems, introduced in [2]), which can

be distinguished from other direct transcription methods by its structure preserving formula-

tion. This is a key feature of the method, since numerical dissipation could lead to over- or

underestimation of the joint torques or muscle forces.

Authors with CRIS profile

Ramona Hoffmann Institute of Applied Dynamics Sigrid Leyendecker Institute of Applied Dynamics

Related research project(s)

Simulation and optimal control of the dynamics of multibody systems in biomechanics and robotics Dec. 1, 2008 - Dec. 1, 2011

Involved external institutions

Friedrich-Schiller-Universität Jena

Germany (DE)

How to cite

APA:

Maas, R., Leyendecker, S., & Siebert, T. (2011). Structure preserving optimal control of finger movements. In Proceedings of the Euromech Colloquium 511 on Biomechanics of Human Motion, DVD, 16 pages (pp. DVD, 16 Seiten). Ponta Delgada, Azores, PT.

MLA:

Maas, Ramona, Sigrid Leyendecker, and Tobias Siebert. "Structure preserving optimal control of finger movements." Proceedings of the Proceedings of the EUROMECH Colloquium 511 on Biomechanics of Human Motion, Ponta Delgada, Azores 2011. DVD, 16 Seiten.

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