# Incompressible Fluid Application

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The aim of this application is to solve the well known set of '''Navier-Stokes''' equations. The problem suffers from severe '''locking''' and/or '''instability''' using linear FEM. | The aim of this application is to solve the well known set of '''Navier-Stokes''' equations. The problem suffers from severe '''locking''' and/or '''instability''' using linear FEM. | ||

+ | <math> | ||

+ | \rho C \frac{\partial T}{\partial t} + \rho C v \cdot \nabla T + \nabla | ||

+ | \cdot q = 0 | ||

+ | </math> | ||

This application solve the the equations.... | This application solve the the equations.... | ||

Mathematical approach to the problems. | Mathematical approach to the problems. | ||

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Insert here all the references to your papers... | Insert here all the references to your papers... | ||

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=== Numerical approach === | === Numerical approach === |

## Revision as of 14:00, 11 December 2009

## Contents |

## General Description

ADVERTISMENT STYLE no numerical details!!! |

### Theory

The aim of this application is to solve the well known set of **Navier-Stokes** equations. The problem suffers from severe **locking** and/or **instability** using linear FEM.

This application solve the the equations.... Mathematical approach to the problems.

Nothing numerical

Insert here all the references to your papers...

### Numerical approach

All numerical details here.

This is a part quite open, depending on the application we are considering.

Every physical problem is solved defining many different ingredients. Try to be quite schematic.