Given values of a piecewise smooth function $f$ on a square grid within a domain $\Omega$, we look for a piecewise adaptive approximation to $f$. Standard approximation techniques achieve reduced approximation orders near the boundary of the domain and near curves of jump singularities of the function or its derivatives. The idea used here is that the behavior near the boundaries, or near a singularity curve, is fully characterized and identified by the values of certain differences of the data across the boundary and across the singularity curve. We refer to these values as the signature of $f$. In this paper, we aim at using these values in order to define the approximation. That is, we look for an approximation whose signature is matched to the signature of $f$. Given function data on a grid, assuming the function is piecewise smooth, first, the singularity structure of the function is identified. For example in the 2-D case, we find an approximation to the curves separating between smooth segments of $f$. Secondly, simultaneously we find the approximations to the different segments of $f$. A system of equations derived from the principle of matching the signature of the approximation and the function with respect to the given grid defines a first stage approximation. An second stage improved approximation is constructed using a global approximation to the error obtained in the first stage approximation.
翻译:鉴于平滑的平滑函数值,我们在一个域内的平方格中寻找一个零碎的适应近似值,以美元为美元。标准近似技术在域的边界附近和函数或其衍生物的跳跃奇点的近似值附近达到减少的近似值。这里使用的想法是,边界附近或接近奇点曲线的行为完全以跨边界和单点曲线数据的某些差异值来描述和识别。我们将这些值称为美元兑美元的签名。在本文中,我们的目标是使用这些值来界定近似值。也就是说,我们寻找一个近似值,其签名与美元兑准相匹配。考虑到在网格上的函数数据,假设函数是平滑的,首先,确定函数的奇点结构。例如,在2-D案中,我们发现一个接近值的曲线是将平滑的美元和超点曲线分辨出。第二,我们同时找到美元兑准值与美元兑准的不同部分的近点值。从第一个阶段开始的方对等值系统,其签名与美元兑合的签名为$f$美元。在第一个阶段将精确度与精确度确定一个全球的精确度。