Simulating Thin Shells by Bicubic Hermite Elements

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC ACS Applied Electronic Materials Pub Date : 2024-05-27 DOI:10.1016/j.cad.2024.103734
Xingyu Ni , Xuwen Chen , Cheng yu , Bin Wang , Baoquan Chen
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Abstract

In this study, we present the bicubic Hermite element method (BHEM), a new computational framework devised for the elastodynamic simulation of thin-shell structures. The BHEM is constructed based on quadrilateral Hermite patches, which serve as a unified representation for shell geometry, simulation, collision avoidance, as well as rendering. Compared with the commonly utilized linear FEM, the BHEM offers higher-order solution spaces, enabling the capture of more intricate and smoother geometries while employing significantly fewer finite elements. In comparison to other high-order methods, the BHEM achieves conforming C1 continuity for Kirchhoff–Love (KL) shells with minimal complexity. Furthermore, by leveraging the subdivision and convex hull properties of Hermite patches, we develop an efficient algorithm for ray-patch intersections, facilitating collision handling in simulations and ray tracing in rendering. This eliminates the need for laborious remodeling of the pre-existing surface as the conventional approaches do. We substantiate our claims with comprehensive experiments, which demonstrate the high accuracy and versatility of the proposed method.

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用双三次赫米特元素模拟薄壳
在本研究中,我们介绍了双立方赫米特元素法(BHEM),这是一种用于薄壳结构弹性动力学模拟的新计算框架。BHEM 基于四边形 Hermite 补丁构建,可作为壳体几何、模拟、避免碰撞以及渲染的统一表示。与常用的线性有限元法相比,BHEM 提供了更高阶的求解空间,可以捕捉到更复杂、更平滑的几何形状,同时大大减少了有限元的使用。与其他高阶方法相比,BHEM 以最小的复杂度实现了基尔霍夫-洛夫(KL)壳的符合 C1 连续性。此外,通过利用 Hermite 补丁的细分和凸壳特性,我们开发出了一种高效的射线-补丁交叉算法,从而方便了模拟中的碰撞处理和渲染中的射线追踪。这样就不需要像传统方法那样费力地重塑原有表面。我们通过全面的实验证实了我们的说法,证明了所提出方法的高准确性和多功能性。
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CiteScore
7.20
自引率
4.30%
发文量
567
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