Sparsity of Runge–Kutta convolution weights for the three-dimensional wave equation

Lehel Banjai; Maryna Kachanovska

doi:10.1007/s10543-014-0498-9

Sparsity of Runge–Kutta convolution weights for the three-dimensional wave equation

Lehel Banjai
, Maryna Kachanovska

Heriot Watt University
Max Planck Institute for Mathematics in the Sciences

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

Abstract

Wave propagation problems in unbounded homogeneous domains can be formulated as time-domain integral equations. An effective way to discretize such equations in time are Runge–Kutta based convolution quadratures. In this paper the behaviour of the weights of such quadratures is investigated. In particular approximate sparseness of their Galerkin discretization is analyzed. Further, it is demonstrated how these results can be used to construct and analyze the complexity of fast algorithms for the assembly of the fully discrete systems.

Original language	English
Pages (from-to)	901-936
Number of pages	36
Journal	BIT Numerical Mathematics
Volume	54
Issue number	4
DOIs	https://doi.org/10.1007/s10543-014-0498-9
Publication status	Published - 1 Dec 2014
Externally published	Yes

Keywords

Convolution quadrature
Runge–Kutta methods
Time-domain boundary integral equations
Wave equation

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10.1007/s10543-014-0498-9

Cite this

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title = "Sparsity of Runge–Kutta convolution weights for the three-dimensional wave equation",

abstract = "Wave propagation problems in unbounded homogeneous domains can be formulated as time-domain integral equations. An effective way to discretize such equations in time are Runge–Kutta based convolution quadratures. In this paper the behaviour of the weights of such quadratures is investigated. In particular approximate sparseness of their Galerkin discretization is analyzed. Further, it is demonstrated how these results can be used to construct and analyze the complexity of fast algorithms for the assembly of the fully discrete systems.",

keywords = "Convolution quadrature, Runge–Kutta methods, Time-domain boundary integral equations, Wave equation",

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AU - Kachanovska, Maryna

PY - 2014/12/1

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N2 - Wave propagation problems in unbounded homogeneous domains can be formulated as time-domain integral equations. An effective way to discretize such equations in time are Runge–Kutta based convolution quadratures. In this paper the behaviour of the weights of such quadratures is investigated. In particular approximate sparseness of their Galerkin discretization is analyzed. Further, it is demonstrated how these results can be used to construct and analyze the complexity of fast algorithms for the assembly of the fully discrete systems.

AB - Wave propagation problems in unbounded homogeneous domains can be formulated as time-domain integral equations. An effective way to discretize such equations in time are Runge–Kutta based convolution quadratures. In this paper the behaviour of the weights of such quadratures is investigated. In particular approximate sparseness of their Galerkin discretization is analyzed. Further, it is demonstrated how these results can be used to construct and analyze the complexity of fast algorithms for the assembly of the fully discrete systems.

KW - Convolution quadrature

KW - Runge–Kutta methods

KW - Time-domain boundary integral equations

KW - Wave equation

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DO - 10.1007/s10543-014-0498-9

M3 - Article

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JO - BIT Numerical Mathematics

JF - BIT Numerical Mathematics

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ER -

Sparsity of Runge–Kutta convolution weights for the three-dimensional wave equation

Abstract

Keywords

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