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| #acl CarstenEden:admin,read,write,delete,revert All:read #format wiki #language en === Python Ocean Model 2.0 (pyOM2) === |
'''Python Ocean Model 2.2 (pyOM2)''' |
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| pyOM2 is a numerical circulation ocean model powered by [[https://www.python.org|Python]]. | |
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| pyOM2 is a simple and easy to use numerical circulation ocean model to configure and to integrate idealized and realistic configurations. |
'''This version and documentation is outdated! Use [[https://github.com/ceden/pyOM2]] instead''' |
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| Features are: | Features are: |
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| * Non-hydrostatic configurations | * Hydrostatic or non-hydrostatic configurations |
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| * several energetically consistent parameterisations | * energetically consistent parameterisations |
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| Fortran and Python version are based on the identical Fortran90 code which is fully parallelized based on the MPI-library to enhance performance. |
* fully parallelized using [[http://www.mpi-forum.org/|MPI]] |
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| === Resources === | Idealized and realistic configurations are simple and easy to configure and to integrate. Fortran and a Python version are based on the identical Fortran90 core code. Several idealized and realistic examples are preconfigured and can be easily chosen and modified using two alternative configuration methods based on Fortran90 or Python. |
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| * [[attachment:pyOM2.pdf|Documentation]] | === Downloads === * [[attachment:pyOM2_3.pdf|Documentation]] |
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| * Source code as [[attachment:pyOM2.1.0.tar.gz|tar ball]] | * Source code at [https://github.com/ceden/pyOM2] |
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| * pyOM2 installed on lightweight Debian system as Virtual box client | === Installation === |
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| === Prerequisites and Installation === | For installation details refer to the [[attachment:pyOM2_2.pdf|Documentation]] |
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| Prerequisites for the Fortran front are Fortran 90 compiler, Lapack and NetCDF library |
=== Idealized configurations === * Vertical shear instability [[TO/pyOM2/Kelvin Helmholtz|configuration]] |
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| Prerequisites for the Python front end is Python and the module Numpy, several other modules can be used to provide a graphical user interface, Netcdf IO, etc |
* Holmboe instability [[TO/pyOM2/Holmboe|configuration]] |
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| For installation details refer to the [[attachment:pyOM2.pdf|Documentation]] | * Internal gravity wave beam [[TO/pyOM2/internal wave|configuration]] |
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| === Sample Configurations === | * Rayleigh-Bernard convection [[TO/pyOM2/Rayleigh Bernard|configuration]] |
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| Several idealized experiments and examples are preconfigured and can be easily chosen and modified using two alternative configuration methods based on Fortran90 or Python. |
* eddy-driven zonal jet [[TO/pyOM2/zonal jets|configuration]] |
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| Here is an example of a vertical shear instability in a 2D non-hydrostatic [[attachment:kelv_helm1.py|configuration]] using the Graphical User Interface |
* the classical Eady problem [[TO/pyOM2/Eady 1|configuration]] |
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| {{attachment:kelv2.png}} | * another Eady setup with linear stability analysis [[TO/pyOM2/Eady 2|configuration]] |
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| === Realistic Configurations === | * small closed basin with wind-driven channel [[TO/pyOM2/ACC 1|configuration]] |
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| * large closed basin and hydrostatic channel [[TO/pyOM2/ACC 2|configuration]] | |
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| a 4x4 deg global ocean [[/4x4 global model|model]] | === Realistic configurations === * 4x4 deg global ocean [[TO/pyOM2/4x4 global model|model]] |
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| 4/3x4/3 deg North Atlantic regional [[/1.3x1.3 North Atlantic model|model]] | * 4x4 deg global ocean with 45 levels [[TO/pyOM2/4x4 global model 45 levels|model]] * 2x2 deg global ocean with 45 levels [[TO/pyOM2/2x2 global model 45 levels|model]] * 1x1 deg global ocean [[TO/pyOM2/1x1 global model|model]] * 4/3 x 4/3 deg North Atlantic regional [[TO/pyOM2/1.3x1.3 North Atlantic model|model]] * 1/3 x 1/3 deg North Atlantic regional model * 1/12 x 1/12 deg North Atlantic regional model |
Python Ocean Model 2.2 (pyOM2)
Introduction
pyOM2 is a numerical circulation ocean model powered by Python.
This version and documentation is outdated! Use https://github.com/ceden/pyOM2 instead
Features are:
* Cartesian or pseudo-spherical coordinate systems
* Hydrostatic or non-hydrostatic configurations
* energetically consistent parameterisations
* Fortran and Python front end
* Graphical User Interface
* fully parallelized using MPI
Idealized and realistic configurations are simple and easy to configure and to integrate. Fortran and a Python version are based on the identical Fortran90 core code. Several idealized and realistic examples are preconfigured and can be easily chosen and modified using two alternative configuration methods based on Fortran90 or Python.
Downloads
Source code at [https://github.com/ceden/pyOM2]
Installation
For installation details refer to the Documentation
Idealized configurations
* Vertical shear instability configuration
* Holmboe instability configuration
* Internal gravity wave beam configuration
* Rayleigh-Bernard convection configuration
* eddy-driven zonal jet configuration
* the classical Eady problem configuration
* another Eady setup with linear stability analysis configuration
* small closed basin with wind-driven channel configuration
* large closed basin and hydrostatic channel configuration
Realistic configurations
* 4x4 deg global ocean model
* 4x4 deg global ocean with 45 levels model
* 2x2 deg global ocean with 45 levels model
* 1x1 deg global ocean model
* 4/3 x 4/3 deg North Atlantic regional model
* 1/3 x 1/3 deg North Atlantic regional model
* 1/12 x 1/12 deg North Atlantic regional model