A variational approach to multirate integration for constrained systems
Leyendecker S, Ober-Blöbaum S (2011)
Publication Language: English
Publication Type: Conference contribution, Conference Contribution
Publication year: 2011
Pages Range: 1-15
Conference Proceedings Title: Proceedings of the ECCOMAS Thematic Conference on Mutlibody Dynamics
Event location: Brussels
Abstract
The simulation of systems with dynamics on strongly varying time scales is quite challenging and demanding with regard to possible numerical methods. A rather naive approach is to use the smallest necessary time step to guarantee a stable integration of the fast frequencies. However, this typically leads to unacceptable computational loads. Alternatively, multirate methods integrate the slow part of the system with a relatively large step size while the fast part is integrated with a small time step. In this work, a multirate integrator for constrained dynamical systems is derived in closed form via a discrete variational principle on a time grid consisting of macro and micro time nodes. Being based on a discrete version of Hamilton’s principle the resulting variational multirate integrator is a symplectic and momentum preserv-
ing integration scheme and also exhibits good energy behaviour. Depending on the discrete approximations for the Lagrangian function, one obtains different integrators, e.g. purely implicit or purely explicit schemes, or methods that treat the fast and slow parts in different ways. The performance of the multirate integrator is demonstrated by means of the several examples.
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APA:
Leyendecker, S., & Ober-Blöbaum, S. (2011). A variational approach to multirate integration for constrained systems. In Proceedings of the ECCOMAS Thematic Conference on Mutlibody Dynamics (pp. 1-15). Brussels, BE.
MLA:
Leyendecker, Sigrid, and Sina Ober-Blöbaum. "A variational approach to multirate integration for constrained systems." Proceedings of the ECCOMAS Thematic Conference on Mutlibody Dynamics, Brussels 2011. 1-15.
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