接触弹性动力学的时间步重网格

Z. Ferguson, T. Schneider, D. Kaufman, Daniele Panozzo
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引用次数: 0

摘要

我们提出了In-Timestep Remeshing,这是一种用于接触弹性动力学的完全耦合自适应网格算法,其中remesmesh步骤在时间步解内隐式地紧密集成。我们的算法通过测量每个持续时间步解内的物理能量变化来自动细化和粗化域。这提供了一致的、自由度高的、高效的重网格,通过构造,它是物理感知的,从而避免了使用时间步进方法重网格时经常遇到的错误、过度细化、工件、每个示例的手动调整和不稳定。然后,我们的时间步长计算确保每个模拟步骤的输出既是更新网格上的收敛稳定解,又是相对于最后一个时间步长的模型和解的时间一致轨迹。同时,保证所有操作的输出是安全的(无交叉和反转)。我们演示了各种极端应力测试的应用,包括具有挑战性的接触、尖锐的几何形状、极端压缩、大时间步长和宽材料刚度范围-所有这些场景都很适合挑战现有的重网格方法。
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In-Timestep Remeshing for Contacting Elastodynamics
We propose In-Timestep Remeshing, a fully coupled, adaptive meshing algorithm for contacting elastodynamics where remeshing steps are tightly integrated, implicitly, within the timestep solve. Our algorithm refines and coarsens the domain automatically by measuring physical energy changes within each ongoing timestep solve. This provides consistent, degree-of-freedom-efficient, productive remeshing that, by construction, is physics-aware and so avoids the errors, over-refinements, artifacts, per-example hand-tuning, and instabilities commonly encountered when remeshing with timestepping methods. Our in-timestep computation then ensures that each simulation step's output is both a converged stable solution on the updated mesh and a temporally consistent trajectory with respect to the model and solution of the last timestep. At the same time, the output is guaranteed safe (intersection- and inversion-free) across all operations. We demonstrate applications across a wide range of extreme stress tests with challenging contacts, sharp geometries, extreme compressions, large timesteps, and wide material stiffness ranges - all scenarios well-appreciated to challenge existing remeshing methods.
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