An Efficient Simulation Method for Large-Scale Systems with Local Nonlinearities
Paper i proceeding, 2016

In practice, most mechanical systems show nonlinear characteristics within the operational envelope. However, the nonlinearities are often caused by local phenomena and many mechanical systems can be well represented by a linear model enriched with local nonlinearities. Conventional nonlinear response simulations are often computationally intensive; the problem which becomes more severe when large-scale nonlinear systems are concerned. Thus, there is a need to further develop efficient simulation techniques. In this work, an efficient simulation method for large-scale systems with local nonlinearities is proposed. The method is formulated in a state-space form and the simulations are done in the Matlab environment. The nonlinear system is divided into a linearized system and a nonlinear part represented as external nonlinear forces acting on the linear system; thus taking advantage in the computationally superiority in the locally nonlinear system description compared to a generally nonlinear counterpart. The triangular-order hold exponential integrator is used to obtain a discrete state-space form. To shorten the simulation time additionally, auxiliary matrices, similarity transformation and compiled C-codes (mex) to be used for the time integration are studied. Comparisons of the efficiency and accuracy of the proposed method in relation to simulations using the ODE45 solver in Matlab and MSC Nastran are demonstrated on numerical examples of different model sizes.

C-code/mex

Triangular-order hold

Locally nonlinear systems

Efficient time integration

State-space

Författare

Yousheng Chen

Linnéuniversitetet, Växjö

Andreas Linderholt

Linnéuniversitetet, Växjö

Thomas Abrahamsson

Dynamik

Conference Proceedings of the Society for Experimental Mechanics Series

21915644 (ISSN) 21915652 (eISSN)

Vol. 6 259-267
978-3-319-29910-5 (ISBN)

Ämneskategorier

Reglerteknik

DOI

10.1007/978-3-319-29910-5_27

ISBN

978-3-319-29910-5

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2024-07-12