Inexpensive polynomial-degree-robust equilibrated flux a posteriori estimates for isogeometric analysis

Gregor Gantner, Martin Vohralík
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Abstract

In this paper, we consider isogeometric discretizations of the Poisson model problem, focusing on high polynomial degrees and strong hierarchical refinements. We derive a posteriori error estimates by equilibrated fluxes, i.e. vector-valued mapped piecewise polynomials lying in the H(div) space which appropriately approximate the desired divergence constraint. Our estimates are constant-free in the leading term, locally efficient, and robust with respect to the polynomial degree. They are also robust with respect to the number of hanging nodes arising in adaptive mesh refinement employing hierarchical B-splines, though not with respect to the smoothness and support overlaps. Two partitions of unity are designed, one with larger supports corresponding to the mapped splines, and one with small supports corresponding to mapped piecewise multilinear finite element hat basis functions. The equilibration is only performed on the small supports, avoiding the higher computational price of equilibration on the large supports or even the solution of a global system. Thus, the derived estimates are also as inexpensive as possible. An abstract framework for such a setting is developed, whose application to a specific situation only requests a verification of a few clearly identified assumptions. Numerical experiments illustrate the theoretical developments.

用于等时线分析的低成本多项式度稳健均衡通量后验估计值
在本文中,我们考虑了泊松模型问题的等几何离散化,重点是高多项式度和强分层细化。我们通过平衡通量推导出后验误差估计值,即位于 H(div) 空间的矢量值映射分片多项式,可适当逼近所需的发散约束。我们的估计值在前导项中是无常数的、局部有效的,并且在多项式度方面是稳健的。对于采用分层 B-样条曲线的自适应网格细化过程中出现的悬挂节点数量,它们也是稳健的,但对于平滑度和支撑重叠则不是。我们设计了两个统一分区,一个是与映射样条曲线相对应的较大支撑点,另一个是与映射片断多线性有限元帽基函数相对应的较小支撑点。均衡只在小支撑上进行,避免了在大支撑上进行均衡的较高计算代价,甚至避免了全局系统的求解。因此,推导出的估计值也尽可能低廉。我们为这种设置开发了一个抽象框架,将其应用于特定情况只需要验证几个明确的假设。数值实验说明了理论的发展。
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