Diff for "TO/pyOM2"

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Python Ocean Model 2.0 (pyOM2)

Contents

Introduction
1. Resources
Prerequisites and Installation
1. Prerequisites
2. Installation
Sample Configurations

Introduction

pyOM2.0 (Python Ocean Model) is a numerical circulation ocean model which was written for educational purpose. It is meant to be a simple and easy to use numerical tool to configure and to integrate idealized and realistic numerical simulations of the ocean in Boussinesq approximation. Non-hydrostatic situations as well as large-scale oceanic flows can be considered, Cartesian or pseudo-spherical coordinate systems can be used.

Several idealized experiments and examples are preconfigured and can be easily chosen and modified using two alternative configuration methods based on Fortran90 or Python. Prerequisites for the installation is a Fortran 90 compiler and the Lapack library, and for the Fortran front the NetCDF-library (since IO is realized mainly using the NetCDF format).

For the Python front end, the numerical module numpy is required and several other modules can be used in addition, e.g. to provide a graphical user interface. Both version are based on identical Fortran90 code which is fully parallelized based on the MPI-library to enhance performance.

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-pyOM2.0 (Python Ocean Model) is a numerical circulation ocean model which was written for educational
purpose. It is  meant to be a simple and easy to use numerical
+pyOM2.0 (Python Ocean Model) is a numerical circulation ocean model which was written for 
educational purpose. It is  meant to be a simple and easy to use numerical
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-chosen and modified using two alternative  configuration methods based on Fortran90 or Python.
+chosen and modified using two alternative configuration methods based on Fortran90 or Python.
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-For the Python front end, the numerical module \verb+numpy+ is required and several
+For the Python front end, the numerical module numpy is required and several
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- a graphical user interface. Both version are based on identical Fortran90 
 code which is fully parallelized  based on the MPI-library to enhance performance.
+a graphical user interface. Both version are based on identical Fortran90 
code which is fully parallelized  based on the MPI-library to enhance performance.
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-=== Kelvin-Helmholtz Instability ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Kelvin-Helmholtz%20Instability|Content Here]]

{{{
kelvin_helm1.py
}}}
=== Rayleigh–Bénard Convection ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Rayleigh–Bénard%20Convection|Content Here]]

{{{
rayleigh.py
}}}
=== Eady's Baroclinic Instability ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Rayleigh–Bénard%20Convection|Content Here]]

{{{
eady1.py / eady2.py
}}}
=== Eddy-driven zonal jets ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Eddy-driven%20Zonal%20Jets|Content Here]]

{{{
jets1.py
}}}
=== Thermohaline Circulation ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Thermohaline%20Circulation|Content Here]]

{{{
THC1.py
}}}
=== Southern Ocean Circulation ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Southern%20Ocean%20Circulation|Content Here]]

{{{
acc1.py
}}}
=== ENSO Response ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/ENSO%20Response|Content Here]]

{{{
enso1.py
}}}
=== Equatorial Waves ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Equatorial%20Waves|Content Here]]

{{{
eq_waves1.py
}}}
=== Isopycnal Diffusion ===
[[https://wiki.zmaw.de/ifm/TO/pyOM/Isopycnal%20Diffusion|Content Here]]

{{{
isopyc_test1.py
}}}
An example of the python GUI for Eady's baroclinic instability case is shown below.

{{attachment:pyOM.png}}

Introduction

Resources

Prerequisites and Installation

Prerequisites

Installation

Sample Configurations