Discrete Lie Advection of Differential Forms

P. Mullen; A. McKenzie; D. Pavlov; L. Durant; Y. Tong; E. Kanso; J. E. Marsden; M. Desbrun

doi:10.1007/s10208-010-9076-y

Discrete Lie Advection of Differential Forms

P. Mullen
, A. McKenzie
, D. Pavlov
, L. Durant
, Y. Tong
, E. Kanso
, J. E. Marsden
, M. Desbrun

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

Abstract

In this paper, we present a numerical technique for performing Lie advection of arbitrary differential forms. Leveraging advances in high-resolution finite-volume methods for scalar hyperbolic conservation laws, we first discretize the interior product (also called contraction) through integrals over Eulerian approximations of extrusions. This, along with Cartan's homotopy formula and a discrete exterior derivative, can then be used to derive a discrete Lie derivative. The usefulness of this operator is demonstrated through the numerical advection of scalar fields and 1-forms on regular grids.

Original language	English
Pages (from-to)	131-149
Number of pages	19
Journal	Foundations of Computational Mathematics
Volume	11
Issue number	2
DOIs	https://doi.org/10.1007/s10208-010-9076-y
Publication status	Published - 1 Jan 2011
Externally published	Yes

Keywords

Discrete Lie derivative
Discrete contraction
Discrete differential forms
Finite-volume methods
Hyperbolic PDEs

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10.1007/s10208-010-9076-y

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keywords = "Discrete Lie derivative, Discrete contraction, Discrete differential forms, Finite-volume methods, Hyperbolic PDEs",

author = "P. Mullen and A. McKenzie and D. Pavlov and L. Durant and Y. Tong and E. Kanso and Marsden, \{J. E.\} and M. Desbrun",

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AU - Mullen, P.

AU - McKenzie, A.

AU - Pavlov, D.

AU - Durant, L.

AU - Tong, Y.

AU - Kanso, E.

AU - Marsden, J. E.

AU - Desbrun, M.

PY - 2011/1/1

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N2 - In this paper, we present a numerical technique for performing Lie advection of arbitrary differential forms. Leveraging advances in high-resolution finite-volume methods for scalar hyperbolic conservation laws, we first discretize the interior product (also called contraction) through integrals over Eulerian approximations of extrusions. This, along with Cartan's homotopy formula and a discrete exterior derivative, can then be used to derive a discrete Lie derivative. The usefulness of this operator is demonstrated through the numerical advection of scalar fields and 1-forms on regular grids.

AB - In this paper, we present a numerical technique for performing Lie advection of arbitrary differential forms. Leveraging advances in high-resolution finite-volume methods for scalar hyperbolic conservation laws, we first discretize the interior product (also called contraction) through integrals over Eulerian approximations of extrusions. This, along with Cartan's homotopy formula and a discrete exterior derivative, can then be used to derive a discrete Lie derivative. The usefulness of this operator is demonstrated through the numerical advection of scalar fields and 1-forms on regular grids.

KW - Discrete Lie derivative

KW - Discrete contraction

KW - Discrete differential forms

KW - Finite-volume methods

KW - Hyperbolic PDEs

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SP - 131

EP - 149

JO - Foundations of Computational Mathematics

JF - Foundations of Computational Mathematics

IS - 2

ER -

Discrete Lie Advection of Differential Forms

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Keywords

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