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Run-Up Simulation of Impulse-Generated Solitary Waves

Laurmaa, Viljami / Picasso, Marco / Steiner, Gilles / Evers, Frederic M. / Hager, Willi H.

A numerical method is presented to accurately simulate paddle-generated impulse waves. An order-one implicit splitting scheme allows advection and diffusion phenomena to be decoupled. Advection is solved using a semi-Lagrangian scheme implemented on a dynamic adaptive octree. This method enables the use of Courant numbers larger than one while the octree is refined at the liquid–air interface. Diffusion is solved on a fixed, unstructured finite-element tetrahedral mesh. Interpolation between octree and finite elements is discussed. Numerical results pertaining to paddle-generated waves in a tilted cavity are successfully compared with experimental data.

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Run-Up Simulation of Impulse-Generated Solitary Waves

Laurmaa, Viljami / Picasso, Marco / Steiner, Gilles / Evers, Frederic M. / Hager, Willi H.

A numerical method is presented to accurately simulate paddle-generated impulse waves. An order-one implicit splitting scheme allows advection and diffusion phenomena to be decoupled. Advection is solved using a semi-Lagrangian scheme implemented on a dynamic adaptive octree. This method enables the use of Courant numbers larger than one while the octree is refined at the liquid–air interface. Diffusion is solved on a fixed, unstructured finite-element tetrahedral mesh. Interpolation between octree and finite elements is discussed. Numerical results pertaining to paddle-generated waves in a tilted cavity are successfully compared with experimental data.

Run-Up Simulation of Impulse-Generated Solitary Waves

Laurmaa, Viljami / Picasso, Marco / Steiner, Gilles / Evers, Frederic M. / Hager, Willi H.

A numerical method is presented to accurately simulate paddle-generated impulse waves. An order-one implicit splitting scheme allows advection and diffusion phenomena to be decoupled. Advection is solved using a semi-Lagrangian scheme implemented on a dynamic adaptive octree. This method enables the use of Courant numbers larger than one while the octree is refined at the liquid–air interface. Diffusion is solved on a fixed, unstructured finite-element tetrahedral mesh. Interpolation between octree and finite elements is discussed. Numerical results pertaining to paddle-generated waves in a tilted cavity are successfully compared with experimental data.

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Title:

Run-Up Simulation of Impulse-Generated Solitary Waves

Contributors:

Laurmaa, Viljami (author) / Picasso, Marco (author) / Steiner, Gilles (author) / Evers, Frederic M. (author) / Hager, Willi H. (author)

Published in:

Journal of Engineering Mechanics ; 144

Publication date:

2017-12-04

ISSN:

0733-9399 , 1943-7889

DOI:

https://doi.org/10.1061/(ASCE)EM.1943-7889.0001385

Type of media:

Article (Journal)

Type of material:

Electronic Resource

Language:

Unknown

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