Hp-finite elements for fractional diffusion

Dominik Meidner; Johannes Pfefferer; Klemens Schürholz; Boris Vexler

doi:10.1137/17M1135517

Hp-finite elements for fractional diffusion

Dominik Meidner
, Johannes Pfefferer
, Klemens Schürholz
, Boris Vexler

Chair of Optimal Control

Technical University of Munich

Research output: Contribution to journal › Article › peer-review

25 Scopus citations

Abstract

The purpose of this work is to introduce and analyze a numerical scheme to efficiently solve boundary value problems involving the spectral fractional Laplacian. The approach is based on a reformulation of the problem posed on a semi-infinite cylinder in one more spatial dimension. After a suitable truncation of this cylinder, the resulting problem is discretized with linear finite elements in the original domain and with hp-finite elements in the extended direction. The proposed approach yields a drastic reduction of the computational complexity in terms of degrees of freedom and even has slightly improved convergence properties compared to the state-of-the-art discretization using linear finite elements for both the original domain and the extended direction. The performance of the method is illustrated by numerical experiments.

Original language	English
Pages (from-to)	2345-2374
Number of pages	30
Journal	SIAM Journal on Numerical Analysis
Volume	56
Issue number	4
DOIs	https://doi.org/10.1137/17M1135517
State	Published - 2018

Keywords

Anisotropic meshes
Discretization error estimates
Finite elements
Fractional Laplace operator
Hp-finite elements
Nonlocal operators

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10.1137/17M1135517

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title = "Hp-finite elements for fractional diffusion",

abstract = "The purpose of this work is to introduce and analyze a numerical scheme to efficiently solve boundary value problems involving the spectral fractional Laplacian. The approach is based on a reformulation of the problem posed on a semi-infinite cylinder in one more spatial dimension. After a suitable truncation of this cylinder, the resulting problem is discretized with linear finite elements in the original domain and with hp-finite elements in the extended direction. The proposed approach yields a drastic reduction of the computational complexity in terms of degrees of freedom and even has slightly improved convergence properties compared to the state-of-the-art discretization using linear finite elements for both the original domain and the extended direction. The performance of the method is illustrated by numerical experiments.",

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author = "Dominik Meidner and Johannes Pfefferer and Klemens Sch{\"u}rholz and Boris Vexler",

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T1 - Hp-finite elements for fractional diffusion

AU - Meidner, Dominik

AU - Pfefferer, Johannes

AU - Schürholz, Klemens

AU - Vexler, Boris

PY - 2018

Y1 - 2018

N2 - The purpose of this work is to introduce and analyze a numerical scheme to efficiently solve boundary value problems involving the spectral fractional Laplacian. The approach is based on a reformulation of the problem posed on a semi-infinite cylinder in one more spatial dimension. After a suitable truncation of this cylinder, the resulting problem is discretized with linear finite elements in the original domain and with hp-finite elements in the extended direction. The proposed approach yields a drastic reduction of the computational complexity in terms of degrees of freedom and even has slightly improved convergence properties compared to the state-of-the-art discretization using linear finite elements for both the original domain and the extended direction. The performance of the method is illustrated by numerical experiments.

AB - The purpose of this work is to introduce and analyze a numerical scheme to efficiently solve boundary value problems involving the spectral fractional Laplacian. The approach is based on a reformulation of the problem posed on a semi-infinite cylinder in one more spatial dimension. After a suitable truncation of this cylinder, the resulting problem is discretized with linear finite elements in the original domain and with hp-finite elements in the extended direction. The proposed approach yields a drastic reduction of the computational complexity in terms of degrees of freedom and even has slightly improved convergence properties compared to the state-of-the-art discretization using linear finite elements for both the original domain and the extended direction. The performance of the method is illustrated by numerical experiments.

KW - Anisotropic meshes

KW - Discretization error estimates

KW - Finite elements

KW - Fractional Laplace operator

KW - Hp-finite elements

KW - Nonlocal operators

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DO - 10.1137/17M1135517

M3 - Article

AN - SCOPUS:85053552073

SN - 0036-1429

VL - 56

SP - 2345

EP - 2374

JO - SIAM Journal on Numerical Analysis

JF - SIAM Journal on Numerical Analysis

IS - 4

ER -

Hp-finite elements for fractional diffusion

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Keywords

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