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High-Order Accurate Adaptive Kernel Compression Time-Stepping Schemes for Fractional Differential Equations

Baffet, Daniel Henri ; Hesthaven, Jan S.

High-order adaptive methods for fractional differential equations are proposed. The methods rely on a kernel reduction method for the approximation and localization of the history term. To avoid complications typical to multistep methods, we focus our study on 1-step methods and approximate the local part of the fractional integral by integral deferred correction to enable high order accuracy. We present numerical results obtained with both implicit and the explicit methods applied to different problems.


Published in:
Journal of Scientific Computing, 72, 3, 1169-1195
Year:
2017
Publisher:
New York, Springer Verlag
ISSN:
0885-7474
Keywords:
fractional differential equations ; Volterra equations ; kernel reduction ; high-order numerical methods ; integral deferred correction ; local schemes
DOI:
10.1007/s10915-017-0393-z
Other identifiers:
View record in Web of Science
Laboratories:
MCSS

Record appears in:
Scientific production and competences > SB - School of Basic Sciences > MATH - Institute of Mathematics > MCSS - Chair of Computational Mathematics and Simulation Science
Peer-reviewed publications
Work produced at EPFL
Journal Articles
Published

Note: The status of this file is: Anyone


 Record created 2016-04-17, last modified 2020-04-20

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