Factorized Runge-Kutta-Chebyshev Methods.

Stephen O'Sullivan

doi:10.21427/d7j039

Factorized Runge-Kutta-Chebyshev Methods.

Stephen O'Sullivan

School of Computer Science

Research output: Contribution to conference › Paper › peer-review

Abstract

The second-order extended stability Factorized Runge-Kutta-Chebyshev (FRKC2) class of explicit schemes for the integration of large systems of PDEs with diffusive terms is presented. FRKC2 schemes are straightforward to implement through ordered sequences of forward Euler steps with complex stepsizes, and easily parallelised for large scale problems on distributed architectures. Preserving 7 digits for accuracy at 16 digit precision, the schemes are theoretically capable of maintaining internal stability at acceleration factors in excess of 6000 with respect to standard explicit Runge-Kutta methods. The stability domains have approximately the same extents as those of RKC schemes, and are a third longer than those of RKL2 schemes. Extension of FRKC methods to fourth-order, by both complex splitting and Butcher composition techniques, is discussed. A publicly available implementation of the FRKC2 class of schemes may be obtained from maths.dit.ie/frkc

Original language	English
DOIs	https://doi.org/10.21427/d7j039
Publication status	Published - 2016
Event	Astronum 2016 - Duration: 6 Jun 2016 → 10 Jun 2016

Conference

Conference	Astronum 2016
Period	6/06/16 → 10/06/16
Other	11th Annual International Conference on Numerical Modeling of Space Plasma Flows

Keywords

extended stability
Factorized Runge-Kutta-Chebyshev
explicit schemes
PDEs
diffusive terms
forward Euler steps
parallelised
distributed architectures
internal stability
acceleration factors
stability domains
RKC schemes
RKL2 schemes
complex splitting
Butcher composition

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10.21427/d7j039Licence: CC BY

Cite this

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title = "Factorized Runge-Kutta-Chebyshev Methods.",

abstract = "The second-order extended stability Factorized Runge-Kutta-Chebyshev (FRKC2) class of explicit schemes for the integration of large systems of PDEs with diffusive terms is presented. FRKC2 schemes are straightforward to implement through ordered sequences of forward Euler steps with complex stepsizes, and easily parallelised for large scale problems on distributed architectures. Preserving 7 digits for accuracy at 16 digit precision, the schemes are theoretically capable of maintaining internal stability at acceleration factors in excess of 6000 with respect to standard explicit Runge-Kutta methods. The stability domains have approximately the same extents as those of RKC schemes, and are a third longer than those of RKL2 schemes. Extension of FRKC methods to fourth-order, by both complex splitting and Butcher composition techniques, is discussed. A publicly available implementation of the FRKC2 class of schemes may be obtained from maths.dit.ie/frkc",

keywords = "extended stability, Factorized Runge-Kutta-Chebyshev, explicit schemes, PDEs, diffusive terms, forward Euler steps, parallelised, distributed architectures, internal stability, acceleration factors, stability domains, RKC schemes, RKL2 schemes, complex splitting, Butcher composition",

author = "Stephen O'Sullivan",

year = "2016",

doi = "10.21427/d7j039",

language = "English",

note = "Astronum 2016 ; Conference date: 06-06-2016 Through 10-06-2016",

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T1 - Factorized Runge-Kutta-Chebyshev Methods.

AU - O'Sullivan, Stephen

PY - 2016

Y1 - 2016

N2 - The second-order extended stability Factorized Runge-Kutta-Chebyshev (FRKC2) class of explicit schemes for the integration of large systems of PDEs with diffusive terms is presented. FRKC2 schemes are straightforward to implement through ordered sequences of forward Euler steps with complex stepsizes, and easily parallelised for large scale problems on distributed architectures. Preserving 7 digits for accuracy at 16 digit precision, the schemes are theoretically capable of maintaining internal stability at acceleration factors in excess of 6000 with respect to standard explicit Runge-Kutta methods. The stability domains have approximately the same extents as those of RKC schemes, and are a third longer than those of RKL2 schemes. Extension of FRKC methods to fourth-order, by both complex splitting and Butcher composition techniques, is discussed. A publicly available implementation of the FRKC2 class of schemes may be obtained from maths.dit.ie/frkc

AB - The second-order extended stability Factorized Runge-Kutta-Chebyshev (FRKC2) class of explicit schemes for the integration of large systems of PDEs with diffusive terms is presented. FRKC2 schemes are straightforward to implement through ordered sequences of forward Euler steps with complex stepsizes, and easily parallelised for large scale problems on distributed architectures. Preserving 7 digits for accuracy at 16 digit precision, the schemes are theoretically capable of maintaining internal stability at acceleration factors in excess of 6000 with respect to standard explicit Runge-Kutta methods. The stability domains have approximately the same extents as those of RKC schemes, and are a third longer than those of RKL2 schemes. Extension of FRKC methods to fourth-order, by both complex splitting and Butcher composition techniques, is discussed. A publicly available implementation of the FRKC2 class of schemes may be obtained from maths.dit.ie/frkc

KW - extended stability

KW - Factorized Runge-Kutta-Chebyshev

KW - explicit schemes

KW - PDEs

KW - diffusive terms

KW - forward Euler steps

KW - parallelised

KW - distributed architectures

KW - internal stability

KW - acceleration factors

KW - stability domains

KW - RKC schemes

KW - RKL2 schemes

KW - complex splitting

KW - Butcher composition

U2 - 10.21427/d7j039

DO - 10.21427/d7j039

M3 - Paper

T2 - Astronum 2016

Y2 - 6 June 2016 through 10 June 2016

ER -

Factorized Runge-Kutta-Chebyshev Methods.

Abstract

Conference

Keywords

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