Mingwu Li, Thomas Thurnher, Zhenwei Xu, Shobhit Jain
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引用次数: 0
摘要
谱子芒福德(SSM)理论已成为构建高维非线性机械系统的严格、低维降阶模型(ROM)的有力工具。直接计算 SSMs 需要明确了解运动方程中的非线性系数,这限制了其对通用有限元求解器的适用性。在这里,我们提出了一种非侵入式算法,用于计算运动方程中的非线性系数和相关的 ROM,最高可达任意多项式阶。我们的表达式和算法适用于具有高达三次阶非线性的系统,包括速度相关非线性项、非对称阻尼和刚度矩阵,因此适用于大量力学问题。我们通过各种复杂度不断增加的 FE 例子,包括包含超过一百万个自由度的微谐振器 FE 模型,证明了所提出的非侵入式方法的有效性。
Data-free Non-intrusive Model Reduction for Nonlinear Finite Element Models via Spectral Submanifolds
The theory of spectral submanifolds (SSMs) has emerged as a powerful tool for
constructing rigorous, low-dimensional reduced-order models (ROMs) of
high-dimensional nonlinear mechanical systems. A direct computation of SSMs
requires explicit knowledge of nonlinear coefficients in the equations of
motion, which limits their applicability to generic finite-element (FE)
solvers. Here, we propose a non-intrusive algorithm for the computation of the
SSMs and the associated ROMs up to arbitrary polynomial orders. This
non-intrusive algorithm only requires system nonlinearity as a black box and
hence, enables SSM-based model reduction via generic finite-element software.
Our expressions and algorithms are valid for systems with up to cubic-order
nonlinearities, including velocity-dependent nonlinear terms, asymmetric
damping, and stiffness matrices, and hence work for a large class of mechanics
problems. We demonstrate the effectiveness of the proposed non-intrusive
approach over a variety of FE examples of increasing complexity, including a
micro-resonator FE model containing more than a million degrees of freedom.