Open access
Date
2022-04-14Type
- Journal Article
Abstract
We analyze rates of approximation by quantized, tensor-structured representations of functions with isolated point singularities in Double-struck capital R-3. We consider functions in countably normed Sobolev spaces with radial weights and analytic- or Gevrey-type control of weighted semi-norms. Several classes of boundary value and eigenvalue problems from science and engineering are discussed whose solutions belong to the countably normed spaces. It is shown that quantized, tensor-structured approximations of functions in these classes exhibit tensor ranks bounded polylogarithmically with respect to the accuracy epsilon is an element of (0,1) in the Sobolev space H-1. We prove exponential convergence rates of three specific types of quantized tensor decompositions: quantized tensor train (QTT), transposed QTT and Tucker QTT. In addition, the bounds for the patchwise decompositions are uniform with respect to the position of the point singularity. An auxiliary result of independent interest is the proof of exponential convergence of hp-finite element approximations for Gevrey-regular functions with point singularities in the unit cube Q = (0,1)(3). Numerical examples of function approximations and of Schrodinger-type eigenvalue problems illustrate the theoretical results. Show more
Permanent link
https://doi.org/10.3929/ethz-b-000543770Publication status
publishedExternal links
Journal / series
Advances in Computational MathematicsVolume
Pages / Article No.
Publisher
SpringerSubject
Quantized tensor train; Tensor networks; Low-rank approximation; Exponential convergence; Schrödinger equationOrganisational unit
03435 - Schwab, Christoph / Schwab, Christoph
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