Numerical codes for solving the boundary layer problems and computing the boundary layer constants (ICPSR doi:10.18419/darus-1256)

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Part 1: Document Description
Part 2: Study Description
Part 5: Other Study-Related Materials
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Document Description

Citation

Title:

Numerical codes for solving the boundary layer problems and computing the boundary layer constants

Identification Number:

doi:10.18419/darus-1256

Distributor:

DaRUS

Date of Distribution:

2021-03-17

Version:

1

Bibliographic Citation:

Eggenweiler, Elissa, 2021, "Numerical codes for solving the boundary layer problems and computing the boundary layer constants", https://doi.org/10.18419/darus-1256, DaRUS, V1

Study Description

Citation

Title:

Numerical codes for solving the boundary layer problems and computing the boundary layer constants

Identification Number:

doi:10.18419/darus-1256

Authoring Entity:

Eggenweiler, Elissa (Universität Stuttgart)

Other identifications and acknowledgements:

Iryna Rybak

Distributor:

DaRUS

Access Authority:

Eggenweiler, Elissa

Access Authority:

Rybak, Iryna

Depositor:

Eggenweiler, Elissa

Date of Deposit:

2021-01-26

Date of Distribution:

2021-01-29

Study Scope

Keywords:

Mathematical Sciences, coupling conditions, porous media, free flow, Stokes, Darcy

Abstract:

Numerical codes (files ending with .edp) for the computation of the boundary layer constants staying in the generalised interface conditions from Eggenweiler & Rybak (2021). The software is meant to be executed using FreeFem++ (see <a href="http://www.freefem.org/">http://www.freefem.org/</a>). Results for the computed boundary layer constants for the two different types of porous media (circles, ellipses) considered in Eggenweiler & Rybak (2021).

Kind of Data:

Program source code

Kind of Data:

Simulation results according to numerical examples in the publictaion Eggenweiler & Rybak (2021).

Notes:

The numerical codes to solve the boundary layer problems from Eggenweiler & Rybak (2021) are meant to be executed using FreeFem++. Simulation results for two different porous-medium geometries are provided in the folders 'circles' and 'ellipses'.

Methodology and Processing

Sources Statement

Data Access

Notes:

The code is licensed under the terms and conditions of the <a href="https://www.gnu.org/licenses/lgpl-3.0">GNU Lesser General Public License (LGPL)</a> version 3 or - at your option - any later version.

Other Study Description Materials

Related Publications

Citation

Bibliographic Citation:

Eggenweiler, E. and Rybak, I.: Effective coupling conditions for arbitrary flows in Stokes-Darcy systems, Multiscale Model. Simul., 2021.

Other Study-Related Materials

Label:

BLP-M.edp

Text:

Code for computation of boundary layer constants M^{j,bl} for j=1,2.

Notes:

application/octet-stream

Other Study-Related Materials

Label:

BLP-N.edp

Text:

Code for computation of boundary layer constants N^{bl}, N_s^{bl}.

Notes:

application/octet-stream

Other Study-Related Materials

Label:

constants_circles

Text:

Boundary layer constants for circular solid inclusions with radius r=0.25. Results corresponding to the publication.

Notes:

text/plain; charset=US-ASCII

Other Study-Related Materials

Label:

constants_ellipses

Text:

Boundary layer constants for elliptical solid inclusions. Results corresponding to the publication.

Notes:

text/plain; charset=US-ASCII

Other Study-Related Materials

Label:

COPYING.LESSER

Notes:

application/octet-stream

Other Study-Related Materials

Label:

pressure_ff.vtu

Notes:

model/vnd.vtu

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Label:

pressure_ff.vtu

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model/vnd.vtu

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Label:

pressure_ff.vtu

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model/vnd.vtu

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pressure_ff.vtu

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model/vnd.vtu

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pressure_ff.vtu

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model/vnd.vtu

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pressure_ff.vtu

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model/vnd.vtu

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pressure_pm.vtu

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model/vnd.vtu

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pressure_pm.vtu

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model/vnd.vtu

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pressure_pm.vtu

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model/vnd.vtu

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pressure_pm.vtu

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model/vnd.vtu

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pressure_pm.vtu

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model/vnd.vtu

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pressure_pm.vtu

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model/vnd.vtu

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README.md

Notes:

text/markdown

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velocity_ff.vtu

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model/vnd.vtu

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velocity_ff.vtu

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model/vnd.vtu

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velocity_ff.vtu

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model/vnd.vtu

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velocity_ff.vtu

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model/vnd.vtu

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velocity_ff.vtu

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model/vnd.vtu

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velocity_ff.vtu

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model/vnd.vtu

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velocity_pm.vtu

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model/vnd.vtu

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velocity_pm.vtu

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model/vnd.vtu

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velocity_pm.vtu

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model/vnd.vtu

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velocity_pm.vtu

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model/vnd.vtu

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velocity_pm.vtu

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model/vnd.vtu

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Label:

velocity_pm.vtu

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model/vnd.vtu