N. Shravani, Gujji Murali, †. MohanReddy, §. MichaelVynnycky
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引用次数: 0
摘要
在本文中,我们提出了基于残差的后验误差估计的抛物型偏微分方程(PDE)与小随机输入数据在l2 P (Ω;l2 (0, t;H 1 (D))-范数,其中(Ω, F, P)为完全概率空间,D为物理域,T > 0为最终时间。这类偏微分方程的产生是由于缺乏对物理模型的完全理解。为此,摄动技术[2019,Arch。第一版。Eng方法。, 26, pp. 1313-1377]利用幂级数对不确定性参数表示精确随机解,由此我们得到解耦确定性问题。然后通过有限元方法在空间上离散每个问题,并通过Crank-Nicolson格式在时间上推进每个问题。在时间方向上引入二次重构以获得最优边界。本文推广了[2009,SIAM J. Sci.]第一版。确定性抛物型偏微分方程与小随机输入数据的抛物型偏微分方程[j]。数值结果证明了该边界的有效性。
A posteriori error estimates for the Crank-Nicolson method: application to parabolic partial differential equations with small random input data
In this article, we present residual-based a posteriori error estimates for the parabolic partial differential equation (PDE) with small random input data in the L 2 P (Ω; L 2 (0 , T ; H 1 ( D )))-norm, where (Ω , F , P ) is a complete probability space, D is the physical domain, T > 0 is the final time. Such a class of PDEs arises due to a lack of complete understanding of the physical model. To this end, the perturbation technique [2019, Arch. Comput. Methods Eng., 26, pp. 1313-1377] is exploited to express the exact random solution in terms of the power series with respect to the uncertainty parameter, whence we obtain decoupled deterministic problems. Each problem is then discretized in space by the finite element method and advanced in time by the Crank-Nicolson scheme. Quadratic reconstructions are introduced to obtain optimal bounds in the temporal direction. The work generalizes the isotropic results obtained in [2009, SIAM J. Sci. Comput., 31, pp. 2757-2783] for the deterministic parabolic PDEs to the parabolic PDE with small random input data. Numerical results demonstrate the effectiveness of the bounds.
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