The time discrete scheme of characteristics type is especially effective for convection-dominated diffusion problems. The scheme has been used in various engineering areas with different approximations in spatial direction. The lowest-order mixed method is the most popular one for miscible flow in porous media. The method is based on a linear Lagrange approximation to the concentration and the zero-order Raviart-Thomas approximation to the pressure/velocity. However, the optimal error estimate for the lowest-order characteristics-mixed FEM has not been presented although numerous effort has been made in last several decades. In all previous works, only first-order accuracy in spatial direction was proved under certain time-step and mesh size restrictions. The main purpose of this paper is to establish optimal error estimates, $i.e.$, the second-order in $L^2$-norm for the concentration and the first-order for the pressure/velocity, while the concentration is more important physical component for the underlying model. For this purpose, an elliptic quasi-projection is introduced in our analysis to clean up the pollution of the numerical velocity through the nonlinear dispersion-diffusion tensor and the concentration-dependent viscosity. Moreover, the numerical pressure/velocity of the second-order accuracy can be obtained by re-solving the (elliptic) pressure equation at a given time level with a higher-order approximation. Numerical results are presented to confirm our theoretical analysis.
翻译:特性类型离散的特性图案对于以对流为主的传播问题特别有效。这个方法在空间方向近似不同的工程地区使用过。最低级混合法最流行的是在多孔介质中不强迫流动的最流行方法。这个方法基于对集中的线性拉格朗近似和对压力/速度的零级拉维阿尔特-图马斯近近近的线性拉格朗近和零级拉格兰特-托马斯近近近于压力/速度。然而,虽然在过去几十年里已经作出了许多努力,但是没有提出对最底层特征混合的FEM的最佳误差估计。在以往的所有工作中,只有空间方向的第一阶精确度在一定的时间步和网状尺寸的限制下得到证明。本文的主要目的是确定最佳误差估计值,即$2美元,即对集中度和压力/速度的第一阶值的第二阶值。为了这个目的,在我们的分析中引入了精度准性准预测,以清除在非线性离子分散/直径直线性水平上的数值速度的精确度,通过不直径直径透度的压-直径直径直径直径直径分析,可以得出压-直压-直径直压-直径直径直压的压的压的压-直压的压的压-直压-直径直径直压-直压-直径直压-直压-直压-直径直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直压-直径。