Guillermo Aparicio-Estrems, Abel Gargallo-Peiró, Xevi Roca
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引用次数: 0
摘要
我们为黎曼空间上的弯曲高阶元素定义了正则化尺寸-形状失真(质量)度量。为此,我们测量给定元素(直边或曲线)与目标度量所确定的拉伸、对齐和大小的偏差。所定义的变形(质量)适用于检查由常数和随点变化的度量确定的黎曼空间上的直边和曲线元素的有效性和质量。这些示例说明,可以最小化变形,使给定高阶(线性)网格的元素曲线化(变形),并尝试用曲线(线性)元素匹配离散目标度量张量的点向拉伸、对齐和大小。此外,生成的网格还同时与目标度量和边界的曲线特征相匹配。最后,为了验证度量感知尺寸-形状变形最小化是否会导致网格逼近目标度量,我们计算了元素边、面和单元的黎曼度量。结果表明,与各向异性的直边网格相比,曲面高阶网格实体的黎曼度量更接近单位。此外,优化后的网格说明了曲面 r 适应在提高函数表示精度方面的潜力。
Defining metric-aware size-shape measures to validate and optimize curved high-order meshes
We define a regularized size-shape distortion (quality) measure for curved high-order elements on a Riemannian space. To this end, we measure the deviation of a given element, straight-sided or curved, from the stretching, alignment, and sizing determined by a target metric. The defined distortion (quality) is suitable to check the validity and the quality of straight-sided and curved elements on Riemannian spaces determined by constant and point-wise varying metrics. The examples illustrate that the distortion can be minimized to curve (deform) the elements of a given high-order (linear) mesh and try to match with curved (linear) elements the point-wise stretching, alignment, and sizing of a discrete target metric tensor. In addition, the resulting meshes simultaneously match the curved features of the target metric and boundary. Finally, to verify if the minimization of the metric-aware size-shape distortion leads to meshes approximating the target metric, we compute the Riemannian measures for the element edges, faces, and cells. The results show that, when compared to anisotropic straight-sided meshes, the Riemannian measures of the curved high-order mesh entities are closer to unit. Furthermore, the optimized meshes illustrate the potential of curved -adaptation to improve the accuracy of a function representation.