Multiresolution kernel matrix algebra

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS ACS Applied Bio Materials Pub Date : 2024-05-09 DOI:10.1007/s00211-024-01409-8

H. Harbrecht, M. Multerer, O. Schenk, Ch. Schwab

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Abstract

We propose a sparse algebra for samplet compressed kernel matrices to enable efficient scattered data analysis. We show that the compression of kernel matrices by means of samplets produces optimally sparse matrices in a certain S-format. The compression can be performed in cost and memory that scale essentially linearly with the number of data points for kernels of finite differentiability. The same holds true for the addition and multiplication of S-formatted matrices. We prove that the inverse of a kernel matrix, given that it exists, is compressible in the S-format as well. The use of selected inversion allows to directly compute the entries in the corresponding sparsity pattern. Moreover, S-formatted matrix operations enable the efficient, approximate computation of more complicated matrix functions such as \({\varvec{A}}^\alpha \) or \(\exp ({\varvec{A}})\) of a matrix \({\varvec{A}}\). The matrix algebra is justified mathematically by pseudo differential calculus. As an application, we consider Gaussian process learning algorithms for implicit surfaces. Numerical results are presented to illustrate and quantify our findings.

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多分辨率核矩阵代数

我们提出了一种用于 samplet 压缩核矩阵的稀疏代数，以实现高效的散点数据分析。我们证明，通过 samplet 压缩核矩阵可以产生特定 S 格式的最佳稀疏矩阵。对于有限可微分的核，压缩的成本和内存与数据点的数量基本成线性关系。S 格式矩阵的加法和乘法也是如此。我们证明，如果存在核矩阵的逆，那么它在 S 格式中也是可压缩的。使用选择反转可以直接计算相应稀疏性模式中的条目。此外，S 格式的矩阵运算可以高效、近似地计算更复杂的矩阵函数，例如矩阵 \({\varvec{A}}^\alpha \) 或 \(\exp ({\varvec{A}})\) 的矩阵 \({\varvec{A}}\)。矩阵代数在数学上是通过伪微分计算来证明的。作为应用，我们考虑了隐式曲面的高斯过程学习算法。我们给出了数值结果，以说明和量化我们的发现。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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